TEXAS TECH UNIVERSITY

Natural Science Research Laboratory

Special Publications

Museum of Texas Tech University

Number 69 29 November 2018

Bats of Saint Lucia, Lesser Antilles

Scott C. Pedersen , Gary G. Kwiecinski, Hugh H. Genoways ; Roxanne J. Larsen ;
Peter A. Larsen , CarletonJ. Phillips ; ajvd Robert J. Baker

Front cover: The bats of Saint Lucia (from upper left to lower right): (row 1) Monophyllusplethodon , Brachypkylla
cavernarum, Sturnirapaulsoni ; (row 2) Artibeus jamaicensis x schwartzi, Ardops nichollsi , Pteronotus davyi ; (row 3)
Noctilio leporinus, Molossus molossus, and Tadarida brasiliensis. Photographs by Gary G. Kwiecinski.

Special Publications

Museum of Texas Tech University

Number 69

Bats of Saint Lucia, Lesser Antilles

Scott C. Pedersen, GaryG. Kwiecinski, HughH. Genoways, Roxanne J. Larsen, Peter A.
Larsen, CarletonJ. Phillips, and Robert J. Baker

Layout and Design: Lisa Bradley

Cover Design: Gary G. Kwiecinski

Production Editor: Lisa Bradley

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Library of Congress Cataloging-in-Publication Data

Special Publications of the Museum of Texas Tech University, Number 69
Series Editor: Robert D. Bradley

Bats of Saint Lucia, Lesser Antilles

Scott C. Pedersen, Gary G. Kwiecinski, Hugh H. Genoways, Roxanne J. Larsen, Peter A. Larsen, Carleton
J. Phillips, and Robert J. Baker

ISSN 0149-1768
ISBN 1-929330-36-7
ISBN13 978-1-929330-36-2

Museum of Texas Tech University
Lubbock, TX 79409-3191 USA
(806)742-2442

Bats of Saint Lucia, Lesser Antilles

Scott C. Pedersen, Gary G. Kwiecinski ; Hugh H. Genoways , Roxanne J. Larsen , Peter A. Larsen,

CarletonJ. Phillips ; and Robert! Baker

Abstract

Eight species of bat have been previously recorded from the island of Saint Lu¬
cia: Noctilio leporinus, Monophyllus plethodon, Artibeus jamaicensis, Brachyphylla
cavernarum, Ardops nichollsi, Sturnira paulsoni, Molossus molossus, and Tadarida
brasiliensis. Herein, we add a ninth species to the fauna— Pteronotus davyi. These
nine species represent nine genera from four families: Noctilionidae, Mormoopidae,
Phyllostomidae, and Molossidae. This fauna includes four trophic guilds: N. lepori¬
nus (piscivore/insectivore), M. plethodon (nectarivore/pollenivore), A. jamaicensis x
schwartzi, B. cavernarum, A. nichollsi, and S. paulsoni (frugivores), and P. davyi, M.
molossus, and T. brasiliensis (insectivores). Based on its geographic location, the bat
fauna of St. Lucia is enigmatic in regard to species dispersal along the Lesser Antillean
archipelago. Natalus stramineus and M. martiniquensis are present on Martinique im¬
mediately to the north, and Micronycteris buriri, P. fuscus, Glossophaga longirostris,
and Artibeus lituratus are found on St. Vincent directly to the south, yet these six species
are conspicuously absent on St. Lucia. Moreover, the St. Lucian population of Artibeus
resides at the northern edge of a fascinating hybrid zone involving three species, A.
jamaicensis, A. planirostris, and A. schwartzi. In light of these observations, we provide
a framework for analyzing the biogeographical patterns of the regional fauna to see if
there is something about St. Lucia that is unique. We posit that a number of complex
geological and ecological factors account for the depauperate bat fauna observed on the
island as well as the formation of the Artibeus hybrid zone in the southern Lesser Antilles.

Key words: biological invasion, Chiroptera, environmental disruption, hybrid
swarm, Mammalia, natural dispersal, natural history, propagule, Pteronotus davyi,
reproduction, Saint Lucia, species richness

Introduction

The first report of a bat from St. Lucia was by
Dobson (1878) based on an adult male Molossus molos¬
sus in the British Museum (Natural History), which had
been purchased from Miss R. Alexander. Subsequently,
seven additional species of bat were collected on St.
Lucia by several individuals, notably: H. S. Branch in
1901 (NMNH) and J. L. Peters in 1925; J. Knox Jones,
Jr., and C. J. Phillips in 1967 (KU); and J. J. Gulledge
in 1971 (AMNH). Their voucher specimens are well
reported in the literature (Dobson 1878; Miller 1902,
1913a, 1913b; Allen 1908, 1911; Andersen 1908;
Shamel 1931; Jones and Schwartz 1967; Koopman
1968; Jones and Phillips 1970; Jones 1978; Swanepoel

and Genoways 1978). In this study, we added the ninth
species to the fauna— Pteronotus davyi.

Perhaps the most remarkable aspect of the bats of
St. Lucia is that the resident population of Artibeus in¬
cludes hybrids between A. jamaicensis and A schwartzi
(P. Larsen et al. 2010). Indeed, the island is located
at the northern edge of an active hybrid zone among
multiple species of Artibeus and therefore traditional
taxonomic assignment of species-level status is prob¬
lematic. The fauna also includes S. paulsoni, a species
endemic to three southern Lesser Antillean islands,
and A. nichollsi, endemic to the Lesser Antilles but not

1

2

Special Publications, Museum of Texas Tech University

found on the southern islands of Barbados and Grenada.
Two species— B. cavernarum and M. plethodon —are
Antillean endemics with geographic ranges extending
from Puerto Rico ( Monophyllus appearing only as a
fossil) in the Greater Antilles southward to the islands
of St. Vincent and Barbados. Of those species occur¬
ring on St. Lucia, three ( Nleporinus, P. davyi, and M.
molossus ) have entered the Lesser Antilles directly
from the South American mainland or via Trinidad,
whereas the fourth species (T. brasiliensis ) entered the
islands from either the west via the Yucatan Peninsula
or Nicaragua, or from Florida in the north.

Members of our research team first visited St.
Lucia 26 to 28 August 1967 when C. J. Phillips and
the late J. K. Jones, Jr., worked two sites in Dauphin
and Gros Islet quarters. Subsequently the island was
visited 24 to 26 May 1987, when H. H. Genoways and
C. J. Phillips focused on the collection of Artibeus near
Marigot Bay. We returned to the island to net additional
bats on the following dates: 15 to 20 June 2007; 29
July to 3 August 2008; and 13 to 16 March 2009. It
is the combination of these data that we report herein
to elucidate the composition and relationships of the
chiropteran fauna of St. Lucia.

Methods and Materials

Geophysical description of the study area .—The
Lesser Antilles is a chain of volcanic islands that lie
along the eastern edge of the Caribbean plate. This
archipelago was initially formed by volcanic eruptions
more than five million years ago (Newman 1965; Lind¬
say et al. 2002) and extends from the Greater Antilles,
nearly to the coast of South America. Islands in the
southern half of the Lesser Antilles were composed
primarily of volcanic ejecta (Fig. 1).

Saint Lucia was formed approximately 2 mil¬
lion years ago, and its geological history has received
considerable attention (Lindsay et al. 2002). The semi¬
circular depression around the Soufriere—the Qualibou
depression—was thought by many to be an ancient
caldera (Wohletz et al. 1986). However, given that the
spectacular Gros and Petit Piton were the remnants of
two large dacitic lava domes formed no more than 300
thousand years ago, Roobol et al. (1983) and Wright
et al. (1984) interpreted the Qualibou depression not
as a caldera, but rather a large gravity slide. Another
extremely violent phase of island building occurred
at the Soufriere Volcanic Centre 40 to 20 thousand
years ago when a series of major eruptions produced
pyroclastic flows that surged southwards thus forming
that southern end of the island (Wright et al. 1984;
Lindsay et al. 2002). Wohletz et al. (1986) proposed
that these eruptions came from the Qualibou depression
itself, whereas others (Roobol et al. 1983; Wright et al.
1984) thought that these eruptions came from vents in
the Central Highlands (Mt. Grand Magazin and Piton
St. Esprit). There was a massive phreatic eruption in

1766 (Lefort de Latour 1787) and a flurry of phreatic
activity from 1839 to 1843 (Breen 1844).

Saint Lucia is located in the Lesser Antilles, a
chain of islands that extends from Sombrero to the north
and to Grenada in the south. Saint Lucia is situated in
the southern portion of this archipelago, 33.5 km south
of Martinique and 46 km north of St. Vincent (Fig. 1).
St. Lucia is 43.5 km long and 22.5 km wide. With a land
area of 616 square km, it is one of the larger islands in
the Lesser Antilles. St. Lucia is characterized by very
rugged mountainous terrain, dominated by a central
ridge running almost the full length of the island, slowly
rising to Mount Gimie (958 m) in the south. From this
central ridge, valleys extend to either coast, some of
which are broad with relatively large areas of flat land
presently occupied by banana (see following section
for scientific names of plant species discussed in text)
plantations, including those at Cul-de-Sac and Roseau.

The island has a tropical marine climate charac¬
terized by a relatively uniform dry season from January
to April and a rainy season from May to August, with
usually sunny, warm weather from September to Oc¬
tober. The mean annual temperature is approximately
26° C at sea level. Annual rainfall varies from 1.52 to
1.57 m in the north to 2.54 to 3.68 m in the mountainous
interior of the south (Toussaint et al. 2009).

Historically, tropical storms and hurricanes are
infrequent, with the majority passing to the north of
Saint Lucia. From 1780 to 2010,16 hurricanes and 46

Pedersen et al.—Bats of Saint Lucia

3

62°0'0"W

60°0'0"W

16°0'0"N

14°0'0"N

12°0'0"N

10°0'0"N

Figure 1. Map of the southern Lesser Antilles, Trinidad, and northern South America, showing the
position of the island of Saint Lucia in relation to other islands and landmasses in the region.

4

Special Publications, Museum of Texas Tech University

tropical storms have impacted the island. The strongest
hurricane to hit St. Lucia in recent history was Hurri¬
cane Allen, a Category 4 storm (202 km/hr maximum
wind speed), which passed just south of the Hewanorra
International Airport on 4 August 1980. St. Lucia
received catastrophic damage including: destruction
of the banana crop, extensive damage to forests, the
leveling of homes, and the deaths of at least 16 people.
Hurricane Dean, a Category 2 hurricane (175 km/hr
maximum wind speed), passed between St. Lucia and
Martinique on 17 August 2007, after our 2007 field sea¬
son. Martinique sustained the most damage from this
storm, but St. Lucia lost 75% of its banana crop, which
was a severe blow to the island’s economy (Caribbean
Hurricane Network 2015). Natural disturbances, such
as landslides and hurricanes, explain why relatively few
of the forest areas display a classic climax structure
(Tomblin 1981; Daltry 2009; Graveson 2009).

Nearly 35% of St. Lucia is still under some form
of forest cover that has been described in detail (Beard
1949; see also Clarke 2009; Daltry 2009; Graveson
2009; Morton 2009; Graveson and Smith 2013). The
rain forests (moist forest) covered 20% of the island
and occupied the higher elevations (typically above 250
m) of the central spine of mountains extending from
the Castries Water Works Reserve and Piton Flore area
in the north across the narrow Barre de Lisle corridor
to the large blocks of forest to the south exemplified
by the Edmund Forest Reserve (Isaac and Bourque
2001). These forests were characterized by trees
such as candlewood, acomat boucan, bois de masse,
laurier canelle, and bwapen mawon. Plantations of
non-native trees, such as blue mahoe and Caribbean
pine, have been placed around the boundaries of the
forest reserves.

Further down the slopes was the lower montane
rain forest, which was well developed on St. Lucia, with
trees reaching 30 m in height in some areas. These for¬
ests were found in the lower reaches of Barre de Lisle
Ridge, Piton Flore, Dennery Water Works Reserve, Au
Leon Peak, and Raillon Negres. Common trees of this
forest type included bois de masse, balata chien, candle-
wood, bois cote, mountain palmetto, and paletuvier.
This secondary rain forest was surrounded by disturbed
habitat associated with abandoned agricultural lands,
forest logged for timber, and areas damaged by tropical

storms and hurricanes in the past. Breadfruit trees were
often seen growing in these areas along with pioneer
trees such as gumtree, maho kochon, and bwa kannon.

Of lesser importance to bats are the dry scrub
woodlands that occupy the low-lying areas along the
east and west coasts and the northern part of the island.
In several places, these areas are degraded through hu¬
man activity such as agriculture, grazing, roads, and
settlements (Gonzalez and Zak 1996). The largest trees
in these areas are white cedar and bay leaf, but two
introduced trees dominate these woodlands, logwood
and acacia. Among the bushes and small trees common
in this habitat were rough-leaf velvetseed, blacktorch,
and cup tree.

Plant names. —The following are the common
and scientific names of plants discussed in the text:
Acacia {Acacia nilotica ), Acomat Boucan {Sloanea
caribaea), Almond (Prunus dulcis), Balata Chien (Pou¬
ter ia pallida), banana (Musa sp.), Bay Leaf (Pimenta
racemosa ), Bitterwood (Simarouba amara ), Blacktorch
(Erithalis fruticosa ), Blue Mahoe (Hibiscus elatus),
Bois Cote (Tapura latifolia), Bois de Masse (Licania
ternatensis ), Breadfruit (Artocarpus altilis). Butter¬
cup Tree ( Cochlospermum vitifolium), Bwa Kannon
(Cecropia schreberiana ), Bwapen Mawon (Magnolia
dodecapetala), Candlewood (Dacryodes excelsa),
Caribbean Pine (Pinus caribbea ), Cocoa (Theobroma
cacao). Coconut ( Cocos nucifera). Cup Tree (Wedelia
calycina). Guava (Psidium guajava), Guinep ( Melicoc-
cus bijugatus), Gumtree (Sapium caribaeum), Lansan
(Protium attenuatum), Laurier Canelle (Phoebe elonga-
ta). Limes (Citrus latifolia). Logwood ( Haematoxylum
campechianum), Maho Kochon (Sterculia caribaea).
Mango (Mangifera indica). Mountain Palmetto (Eu¬
terpe globosa). Nutmeg (Myristica fragrans), Pale¬
tuvier (Tovomita plumieri), pepper plant (Piper sp.),
Rough-leaf Velvetseed (Guettarda sacabra), Soursop
(Annona muricata), Swizzlestick Tree ( Quararibea
turbinata). Tree Ferns (Cyathea arborea), and White
Cedar (Tabebuia heterophylla or T. pallida).

Collection of specimens. —We explored and
collected specimens from two caves in 2007, Grace
Cave and Soufriere Cave. However, field collection
and sampling was accomplished primarily by ground
level mist netting. We set 127 mist nets at 21 unique

Pedersen et al.—Bats of Saint Lucia

localities (Barre de l’Isle was sampled twice), during
four different time periods: 24-26 May 1987; 14-20
June 2007; 28-31 July and 1-3 August 2008; and 12-16
March 2009. These nets were set at elevations ranging
from 1 to 550 m and were equally distributed above
and below 250 m in elevation. They were also equally
distributed on the western (wet) and eastern (dry) halves
of the island. Netting was conducted in a variety of
habitats including naturally vegetated ravines or ghuts,
access roads, trails, rivers, ponds, fruit plantations,
forest plantations and reserves, botanical gardens, and
other covered flyways. At each netting site, five to eight
mist nets (2.8, 6, 9, 12 or 18 m length by 2.8 m height)
were set at 20 to 100 m intervals depending on local
landscape features, i.e., width of access roads or rivers,
forest edge, vegetated dry and wet ghuts, small fruit
plantations, and freshwater ponds. Nets were opened
near sunset (1800-1900 hr) and closed between 2200
and 2300 hr each night, depending on weather and
bat activity. Bats caught in nets were placed in hold¬
ing bags until the end of the netting each night. Bats
were subsequently examined for: weight (g), length
of forearm (mm), reproductive condition, tooth wear,
presence of ectoparasites, and scars.

For comparisons with our 1987 and 2007-2009
collections on St. Lucia, we drew additional netting data
from similar survey efforts on both Martinique (Catze-
flis et al., personal communication) and St. Vincent
(Kwiecinski et al. 2018). These data were parsed into

5

island-wide bat diversity and the diversity observed at
netting locations that were located away from known
roosts. The latter varied amongst the three neighbor¬
ing islands (Martinique, 24; St. Lucia, 20; and St.
Vincent, 28) as did the number of bats that were netted
at these particular locations (1,859, 1,520, and 1,679,
respectively). However, netting locations on wet and
dry (west versus east) sides of these islands (-13:11,
10:10, 14:14) and the distributions of net sites above
and below 250 mare comparable (12:12,10:10,14:14).

Minitab 16 (2010) provided standard statistics
for each sample set examined and paired t-tests were
utilized to test for differences between groups. Species
curves were generated in JMP 12 (2015) and R was
used in the multiple regression analysis (R Develop¬
ment Core Team 2008).

Museum voucher specimens .—During the 2007-
2009 surveys, we captured 1,624 bats, 1,248 of which
were captured/released. We deposited 376 voucher
specimens in the mammal collections of the Museum of
Texas Tech University. We examined 72 bats (UNSM)
that had been collected by two of the authors (HHG and
CJP) in 1987. We examined 122 additional specimens
that were collected before 1987 that were deposited in
other museums: American Museum of Natural History,
2; Kansas Museum of Natural History, 32; and National
Museum of Natural History, 88 (see Appendix). There
are no fossil records of bats from this island.

Systematic Accounts

The species accounts that follow are arranged in
systematic order (Simmons 2005; Baker et al. 2016;
Cirranello et al. 2016). Given that the nine genera of
bats recorded from St. Lucia are monotypic on the is¬
land, we refer to these taxa by genus, where pragmatic.
These data are drawn from both the authors’ inventory
efforts on St. Lucia and data from museum specimens.
A list of specimens and a list of additional records are
included. Weights were determined with a digital bal¬
ance and recorded in grams (g). Forearms were mea¬
sured with digital calipers and recorded in millimeters

(mm). All measurements of embryos are crown-rump
length (mm). Testes were measured for length (mm).
Distances were recorded in kilometers (km) or miles as
they appeared on original specimen tags. All elevations
are reported in meters (m), unless specified otherwise.
Length of forearms and cranial measurements were
taken from museum vouchers following Hall (1946),
except greatest length of skull included incisors, and
length of forearm was the distance from the olecranon
process of the elbow joint to the tip of the carpals with
wing in the retracted position.

6

Special Publications, Museum of Texas Tech University

Family Noctilionidae

Noctilio leporinus mastivus (Vahl, 1797)
Greater Fishing Bat

Specimens examined (6).—Anse La Raye: Anse
La Raye, 1 m [13°56'30.3"N, 61°02'28.2"W], 4 (TTU
110080-83). Micoud: Canelles River, 1.5 km S Anse
Ger, 10 m [13°46'59.6"N, 60°54'53.1"W], 1 (TTU
110084). No Specific Quarter: no specific locality, 1
(NMNH 110922).

Additional records .—Soufriere: Edmund For¬
est Reserve (Clarke 2009). No Specific Quarter: no
specific locality (Allen 1911).

This species represents a recent radiation within
the genus Noctilio , having diverged from its sister spe¬
cies N. albiventris within the last million years (Pavan
et al. 2013; Khan et al. 2014). Owing to the species’
recent evolutionary history, studies focused on the
intraspecific morphological and genetic variation of
N. leporinus have resulted in conflicting taxonomic
assessments. Davis (1973) identified three subspecies
within N. leporinus — N. 1. leporinus (distributed in
South America east of the Andes Mountains, through¬
out Amazonia and the Guyana Shield); N. 1. mastivus
(distributed throughout Central America, the Carib¬
bean, and in South America throughout Venezuela and
along the western versant of the Andes Mountains into
northern Ecuador), and N. 1. rufescens (distributed in
southern South America throughout Bolivia, Paraguay,
northern Argentina and southern Brazil). However, ge¬
netic data presented in Pavan et al. (2013) and Khan et
al. (2014) reveal two main lineages within N. leporinus ,
one corresponding to N. 1. mastivus and the other to
N. 1. leporinus. To date, all specimens collected from
within the range of N. 1. rufescens are genetically in¬
distinguishable from N. 1. leporinus (Pavan et al. 2013;
Kahn et al. 2014).

Phylogeographic data from N. leporinus indicates
dual invasions into the Caribbean, with the Greater An¬
tilles being colonized by Central American populations
and the Lesser Antilles colonized by northern South
American populations (Lewis-Oritt et al. 2001a, 2001b;
Genoways et al. 2010; Pavan et al. 2013; Kahn et al.
2014). There was no clear genetic consensus regard¬
ing the appropriate subspecific taxonomy for southern

Lesser Antillean populations ofV. leporinus. A putative
hybrid zone between N. 1. mastivus and N. 1. leporinus
was identified by Khan et al. (2014) in eastern Ven¬
ezuela and the Guyana Shield, the regions from which
southern Lesser Antillean populations presumably
originated (Genoways et al. 2010; Khan et al. 2014).
Additional research will be required to determine the
extent of hybridization in mainland populations of N.
leporinus and whether or not this hybrid zone has in¬
fluenced southern Lesser Antillean populations. With
respect to Caribbean N. leporinus , we recommend the
usage of advanced genomic techniques to examine the
evolutionary history of Greater Antillean and Lesser
Antillean populations and to more precisely identify
zones of secondary contact between N. 1. mastivus and
N. 1. leporinus. Until such data become available, we
provisionally retain N. 1. mastivus for the St. Lucia
population.

Table 1 presents length of forearm and seven
cranial measurements for four males and two female
Noctilio from St. Lucia. As is typical for this spe¬
cies, males averaged larger than females for all seven
measurements. The average forearm and five of seven
cranial measurements were not significantly different
between the sexes. The zygomatic breadth and length
of maxillary toothrow were significantly (P < 0.05)
larger in males than females. In comparison with
measurements from other West Indian females (Davis
1973), measurements for females from St. Lucia were
within ranges reported for the West Indies except
breadth across the upper molars was smaller in the St.
Lucia sample.

This species is widespread in the Antilles, being
found in non-arid lowland and coastal regions and in
major river basins (Hood and Jones 1984). H. S. Branch
collected the oldest known specimen of Noctilio from
St. Lucia in 1901 (NMNH 110922) from an unspeci¬
fied locality. We collected Noctilio on St. Lucia at two
localities, foraging over a coastal inlet in Anse La Raye
on the west coast and the Canelles River on the east
coast (Fig. 2).

At Anse La Raye, we placed three mist nets over
the Petite Riviere de l’Anse La Raye, which was ap¬
proximately 4 m wide, at the point it crossed under the
coastal highway at the north edge of town (Fig. 3). Two

Pedersen et al.—Bats of Saint Lucia

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Range (62.0-67.1) (30.3-32.5) (27.6-29.7) (16.1-17.8) (6.1-6.6) (14.2-15.4) (10.8-11.6) (10.8-12.2)

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Range ( 39 . 3 - 41 . 3 ) ( 16 . 7 - 17 . 3 ) ( 15 . 3 - 15 . 7 ) ( 10 . 3 - 11 . 0 ) ( 3 . 3 - 3 . 7 ) ( 10 . 0 - 10 . 6 ) ( 5 . 8 - 6 . 0 ) { 7 . 4 - 7 . 7 )

Pedersen et al.—Bats of Saint Lucia

9

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Figure 2. Map of the geographic distribution of Noctilio
leporinus and Ardops nichollsi on the Lesser Antillean
island of St. Lucia. Symbols represent: closed diamonds,
specimens examined for Noctilio leporinus ; open
diamond, literature record of Noctilio leporinus ; closed
circles, specimens examined for Ardops nichollsi\ open
circles, literature records of Ardops nichollsi.

of the nets were placed at the east and west openings
under the bridge to cover as much flight space under
the bridge as possible. Beyond the bridge in both di¬
rections were concrete bridge abutments that were as
high as 5 m, and downstream from the bridge the river
ran another 200 m before emptying into the harbor.
Three Noctilio captured on this night were taken in
these nets associated with the bridge. The third mist
net was placed about 70 m upstream at the river’s first
fork. The fourth Noctilio of the evening was taken in
this net. Eight Artibeus captured at this locality were
taken in the same nets that caught the Noctilio.

Five mist nets were placed along the Canelles
River upstream from the bridge where the river passed
under the Micoud Highway. Two mist nets were placed
across the river itself and three additional nets were
used to bracket the gravel road adjacent to the river

10

Special Publications, Museum of Texas Tech University

Figure 3. Photograph of Petite Riviere de FAnse La Raye,
Anse La Raye Quarter, St. Lucia. Three Noctilio leporinus
were captured in mist nets set adjacent to this bridge.

where there were banana plants and scattered mango
trees. Along the road and between the road and river
was highly degraded dry scrub woodland, with shrubs
and small trees. The riverbank was severely eroded
with steep sides that made access to the river a chal¬
lenge. A single Noctilio was captured in a 6 m mist net
set across the river. Other species of bats caught along
the road wer q A. jamaicensis x schwartzi, P. davyi, and
M. molossus.

During the survey work by Clarke (2009) on
St. Lucia, an adult female Noctilio was netted in wet
forest at 550 m elevation at Edmund Forest Reserve.
The bat was taken on a wide trail that lacked canopy
cover. Numerous small streams flowed through the
area, which was largely planted with blue mahoe and
other non-native trees. This was an unusual record
because the site was far from the coast and any large
river or lakes.

Only one female Noctilio was taken during our
work on St. Lucia. This individual was captured on
the evening of 3 August 2008 and evinced no gross
reproductive activity. Two adult males taken on this
same night had testes lengths of 10 and 12, whereas
both young adult males had testes lengths of 3. Based
on the summary of the reproductive cycle of this species
by Hood and Jones (1984), August should be part of a
period of reproductive inactivity for Noctilio.

This adult female weighed 51.7, whereas the two
adult males weighed 65.0 and 65.8 and two young adult
males weighed 52.5 and 53.8.

Both color phases known in this species were
collected on St. Lucia. The pelage of the female was
an overall dark yellowish color, whereas three of the
males exhibited russet venters.

Family Mormoopidae
Pteronotus davyi davyi Gray, 1838
Davy’s Naked-backed Bat

Specimens examined (21).—Castries: Barre
de Lisle Ridge, 0.5 km S, 1.3 km E Rivine Pois¬
son, 294 m [13°55'35.3"N, 60°57'32.0"W], 7 (TTU
110296-99, 110305-07); Forestiere Forest Trailhead,
0.5 km S, 0.5 km E Forestiere, 300 m [13 0 58'11.2"N,
60°57'08.8"W], 1 (TTU 110295). Dennery: Au
Leon Peak, 1 km N, 1.75 km E La Ressource, 319 m
[13°57T4.4"N, 60°54'07.1"W], 5 (TTU 112640-44).
Laborie: 1.25 km N, 0.75 km E Saltibus, 398 m
[13°48'59.8"N, 61 o 00'21.9"W], 2 (TTU 112645-46).
Micoud: Canelles River, 1.5 km S Anse Ger, 10 m
[13°46'59.6"N, 60 o 54'53.1"W], 2 (TTU 110302-03);
Forest Reserve, 2.5 km N, 8 km W Micoud, 283 m
[13°50'23.1"N, 60°58'25.8"W], 2 (TTU 110300-01).
Praslin: Raillon Negres, 1.2 km N, 2.3 km W Mon
Repos, 255 m [13°52'25.3"N, 60°56'09.6"W], 1 (TTU
110304). Soufriere: Edmund Forest Reserve, 0.7 km
N, 1.5 km E Fond St. Jacques, 550 m [13°50'27.9"N,
60°59'47.6"W], 1 (TTU 110308).

Additional records (Clarke 2009).—Anse La
Raye: “Anse La Raye” [= Venus Estate] [converted
from UTM, 13°55T4.7 M N, 61°01T2.1"W]. Castries:
Barre de Lisle Ridge, 0.5 km S, 1.3 km E Rivine Pois¬
son, 294 m [13°55'35.3"N, 60°57'32.0"W]. Praslin:
“Durocher” [= Morne Durocher] [converted from
UTM, 13°52'34.4"N, 60°56T2.5"W].

Specimens captured/released (4).—Castries:
Barre de Lisle Ridge, 0.5 km S, 1.3 km E Rivine Pois¬
son, 294 m [13°55'35.3"N, 60°5732.0"W], 3. Laborie:
1.25 kmN, 0.75 km E Saltibus, 398 m [13°48'59.8"N,
61°00 , 21.9"W], l

Pedersen et al.—Bats of Saint Lucia

Acoustic records. —Clarke (2009) recorded this
species at four of his 16 field sites: Castries: Barre de
l’lsle Ridge. Dauphin: Mount Gaiac. Praslin:Morne
Durocher. Soufriere: Edmund forest.

In 2007, we collected Pteronotus davyi for the
first time from St. Lucia (Fig. 4). This was not a
surprise given that it is found on several islands in the
region: Marie Galante (Masson et al. 1990; Timm and
Genoways 2003), Dominica (Genoways et al. 2001),
Martinique (Issartel and Lablanc 2004; Barataud et al.
2011), and Grenada (Genoways et al. 1998). However,
our surveys failed to find this species on Barbados
(Genoways et al. 2011), the Grenadines (Genoways et
al. 2010), and St. Vincent (Kwiecinski et al. 2018). The
congeneric Pteronotus fuscus was found immediately
to the south on the island of St. Vincent where P. davyi
has not been documented (Vaughan 1995; Vaughan and
Hill 1996; sensu Kwiecinski et al. 2018).

Figure 4. Map of the geographic distribution of
Pteronotus davyi on the Lesser Antillean island of
St. Lucia. Symbols include: closed circles represent
specimens examined and open circles represent literature
records.

11

Smith (1972) revised members of the family
Mormoopidae. Although he noted some morphological
differences among the populations, he assigned bats oc¬
curring in Nicaragua, Costa Rica, Venezuela, Trinidad,
and on several of the Lesser Antilles to the nominate
subspecies, P. d. davyi. Genoways et al. (2001) re¬
ported that individuals of this bat from the island of
Dominica were significantly larger in greatest length
of skull (P < 0.01) and breadth of braincase (P < 0.05)
than a sample from Trinidad, which is the type local¬
ity for P. davyi. They also found that the sample from
Trinidad was significantly larger than the material from
Dominica in postorbital constriction (P < 0.05). The
inclusion of the St. Lucia material into this mix adds
to the confusion. In length of forearm and five cranial
measurements, the sample from St. Lucia averaged
smaller than the samples from Dominica and Trinidad,
whereas the sample from St. Lucia averaged the largest
of the three populations for condylobasal length and
postorbital constriction. Recently, Pavan and Marroig
(2016) found that 14 individuals of P. davyi that we
collected on St. Lucia were closely related to those on
Trinidad and Dominica, that is, less than 1% sequence
divergence in mitochondrial cytochrome-# gene DNA
sequence data. We thereby apply the name P. d. davyi
to these island populations following both Smith (1972)
and Pavan and Marroig (2016).

Table 1 presents length of forearm and seven
cranial measurements for six male and six female
Pteronotus from St. Lucia. Smith (1972) found little
secondary sexual variation in any mormoopid. Our
data support this finding with no significant difference
being found between males and females in the eight
measurements tested. Males averaged larger than
females in two measurements (length of forearm and
greatest length of skull) and females averaged larger
in two measurements (postorbital constriction and
mastoid breath), with the means for the four remaining
measurements being the same for the sexes.

We netted at the Barre de Lisle Ridge site on two
occasions (19 June 2007 and 3 August 2008). This
steep, narrow ridge extends from the northern high¬
lands and rainforests of the central axis of mountains
to the southern highlands with their rainforests and
delineates the Atlantic from the Caribbean watersheds.
At 294 m, it is one of lower points along the divide,

12

Special Publications, Museum of Texas Tech University

serving as a pass for the major east-west highway on
the island. The ridge was covered with rainforest at its
highest levels, which were flanked by well-developed
lower montane rainforest, with trees reaching 30 m
in height in some areas. Common trees of this forest
type include candlewood, bois de masse, balata chien,
bois cote, and paletuvier. We noted old tree stumps in
the area, indicating at least some selective logging had
occurred. In general, nets were set along the ridge top
along an access road that led from a picnic area just
south of the main highway then northward to the where
the road dropped quickly down the eastern side of the
ridge (Fig. 5). During our first visit to the site, we net¬
ted in fog. We captured the same six species of bats
during both visits to the site. A total of 10 Pteronotus
were obtained here, more than at any other place on
the island. The other five species taken each year were
the five species of fruit bats known from St. Lucia: M.
plethodon (61), B. cavernarum (9), A. nichollsi (12),
A.jamaicensis x schwartzi (129), and S. paulsoni (18).

The night of 16 March 2009, we worked along
the top of a steep ridge that marked the northern limit
of the Mabouya Valley. Au Leon Peak was one of the
high points along this ridge. The ridge had been logged
in the past and replaced with plantations of blue mahoe

Figure 5. Photograph of the secondary tropical forest
along Barre de Lisle Ridge, Castries Quarter, St. Lucia.
Ten Pteronotus davyi were captured along trails in this
forest on two nights of mist netting.

and Caribbean pine. The slopes in many places were
relatively open with short (1-1.5 m) pioneer vegeta¬
tion. We placed six nets along the access road and
small paths that intersected the road. In some places,
the high banks along the road formed a flyway for the
bats. This was one of three places on the island that we
caught seven species of bats in a single night. These
included two insectivorous bats— P davyi (5) and M.
molossus (8)—and the five species of frugivores known
from the island— M. plethodon (2), A. nichollsi (4), B.
cavernarum (3), A.jamaicensis x schwartzi (18), and
S. paulsoni (1).

Eight Pteronotus were captured on St. Lucia on
16 and 17 March 2009, of which four were pregnant
females with embryos measuring 8,10,10, and 14, two
were females evincing no gross reproductive activity,
and two were scrotal males with testes measuring 3 in
length. Clarke (2009) reported capturing one pregnant
female on St. Lucia on 6 April. Only four males were
obtained during our netting efforts between 17 and 20
June 2007, with three being scrotal males with testes
of 3 in length and one male with testes in an inguinal
position measuring 2 in length. Of six females captured
on St. Lucia during our field studies 1 to 4 August 2008,
four were lactating and two evinced no reproductive
activity. Four males netted between 31 July and 4 Au¬
gust had testes in a non-scrotal position and had testes
lengths of 1,2,3, and 4. The reproductive data from our
study matches the seasonal monoestry cycle found in
previous studies for this species (Wilson 1973; Adams
1989). Breeding occurs in January and February, with
gestation through the spring dry season. Births were
timed for the onset of the rainy season in May and June,
with lactation occurring through July into early August.
Near full-term embryos had a crown-rump length of
25 (Adams 1989).

Weights of Pteronotus recorded from St. Lucia
were as follows: mid-March—pregnant females, 7.2,
7.4,7.4,7.5; non-reproductive females, 7.1,7.4; scrotal
males, 6.8,6.9; mid-June—scrotal males, 7.7, 8.1,9.1;
non-scrotal male, 8.1; late July-early August—lactating
females, 7.5, 7.8, 7.8, 7.9; non-reproductive females,
7.6, 7.6; non-scrotal males, 7.1, 7.5, 7.6, 8.9.

Pedersen et al.—Bats of Saint Lucia

Family Phyllostomidae

Monophyllus plethodon plethodon Miller, 1900
Insular Single-leaf Bat

Specimens examined (46).—Castries: Barre de
Flsle Ridge, 0.5 km S, 1.3 km E Rivine Poisson, 294
m [13°55'35.3"N, 60°57'32.0"W], 2 (TTU 110009-10);
Forestiere Forest Trailhead, 0.5 km S, 0.5 km E For¬
estiere, 300 m [13°58T1.2"N, 60°57'08.8"W], 7 (TTU
109988-109994); Marigot Bay, 1 (UNSM 16568);
Piton Flore, Forestiere Forest Trail, 1.2 km S, 1.9 km
E Forestiere, 300 m [13°57'51.6"N, 60°56'24.0"W],

1 (TTU 109995). Dennery: Au Leon Peak, 1 km
N, 1.75 km E La Ressource, 319 m [13°57T4.4"N,
60°54'07.1"W], 2 (TTU 111488-89). Laborie: 1.25
km N, 0.75 km E Saltibus, 398 m [13°48'59.8"N,
61°00'21.9"W], 5 (TTU 111490-94). Micoud: Qui-
lesse Forest Reserve, 2.5 km N, 8 km W Micoud, 283
m [13°50'23.1"N, 60°58'25.8"W], 7 (TTU 109997-
110003); Troumassee River, 1.3 km W Micoud, 40
m [13°49T3.9"N, 60°54'53.7"W], 1 (TTU 109996).
Praslin: Fox Grove Inn, 1.1 km N, 0.2 km W Mon
Repos, 52 m [13°51'47.0"N, 60°54'22.8"W], 1 (TTU
110004); Raillon Negres, 1.2 km N, 2.3 km W Mon
Repos, 255 m [13°52'25.3"N, 60°56'09.6"W], 4 (TTU
110005-08). Vieux Fort: Woodland Estate, 2.25 kmN,
1.3 km WGrace, 211 m [13 0 4T54.7"N, 60°58'50.7 M W],

2 (TTU 110011-12). No Specific Quarter: no specific
locality, 13 (NMNH 106090-94, 110901-05).

Additional records (Clarke 2009, unless other¬
wise noted).—Anse La Raye: Millet Forest [= Millet
Bird Sanctuary] [converted from UTM, 13°53'44.7"N,
60°59'50.2"W], Castries: Barre de Flsle Ridge, 0.5
km S, 1.3 km E Rivine Poisson, 294 m [converted
from UTM, 13°55'35.3"N, 60°57'32.0"W]. Praslin:
“Durocher” [= Morne Durocher] [converted from
UTM, 13°52'34.4"N, 60°56T2.5"W]. No Specific
Quarter: no specific locality (Miller 1902; Schwartz
and Jones 1967).

Specimens captured/released (127).—Castries:
Barre de Flsle Ridge, 0.5 km S, 1.3 km E Rivine
Poisson, 294 m [13°55'35.3"N, 60°57'32.0"W], 59;
Forestiere Forest Trailhead, 0.5 km S, 0.5 km E
Forestiere, 300 m [13°58'11.2"N, 60°57'08.8"W],
3. Dennery: Dennery River, 0.25 km S, 2 km W
Dennery, 11 m [13°54'34.6"N, 60°54'16.2"W], 1.

13

Laborie: 1.25 km N, 0.75 km E Saltibus, 398 m
[13°48'59.8"N, 61°00'21.9"W], 1. Micoud: Quilesse
Forest Reserve, 2.5 km N, 8 km W Micoud, 283 m
[13°50'23.1"N, 60°58'25.8"W], 52. Praslin: Rail¬
lon Negres, 1.2 km N, 2.3 km W Mon Repos, 255 m
[13°52'25.3"N, 60°56'09.6"W], 3. Soufriere: Edmund
Forest Reserve, 0.7 kmN, 1.5 km E Fond St. Jacques,
550 m [13°50'27.9"N, 60°59'47.6"W], 6. Vieux Fort:
Woodland Estate, 2.25 km N, 1.3 km W Grace, 211m
[13°47'54.7"N, 60°58'50.7"W], 2.

Miller (1902) originally described the Monophyl¬
lus on St. Lucia under the name Monophyllus luciae ,
based on 13 specimens collected by H. S. Branch in
1901 from two unspecified sites, one of which was in
the Laborie Quarter. Schwartz and Jones (1967) revised
M. plethodon , recognizing two extant subspecies, M.
p. plethodon and M. p. luciae. Schwartz and Jones
(1967) restricted the nominate subspecies to Barbados,
whereas populations of M. plethodon from throughout
the remainder of the Lesser Antilles, from Anguilla
southward to St. Vincent, were assigned to M. p. luciae.
A fossil from Puerto Rico was recognized under the
name M. p.frater. When Schwartz and Jones (1967)
studied M. plethodon , they stated: “It is purely on the
basis of the holotype that we recognize M. p. plethodon
as distinct from other Lesser Antillean populations.”
The holotype of M. p. plethodon was smaller than other
specimens of M. plethodon , including the second speci¬
men from Barbados. Schwartz and Jones (1967) were
uncertain about their decision in recognizing both M. p.
plethodon and M. p. luciae and opined that additional
material from these islands could alter their decision.
A genetic analysis of St. Lucian M. plethodon remains
to be conducted.

With adequate samples available from both
Barbados and St. Lucia, Genoways et al. (2011) ex¬
amined the morphological variation between these
populations. Surprisingly, the males from St. Lucia
were significantly different from those on Barbados
in five of seven measurements, whereas the females
were significantly different in only two measurements
and, in fact, females from these two islands averaged
the same in four measurements. The males from
St. Lucia were significantly smaller than those from
Barbados in four (greatest length of skull, zygomatic
breadth, postorbital constriction, and mastoid breadth)

14

Special Publications, Museum of Texas Tech University

of the five measurements. Males from St. Lucia were
significantly larger than those from Barbados in length
of the maxillary toothrow. The females from St. Lucia
were significantly larger than those from Barbados in
two measurements—length of forearm and length of
the maxillary toothrow. Based on these results, Geno-
ways et al. (2011) concluded that M. plethodon from
Barbados were not smaller than those on St. Lucia as
supposed by Schwartz and Jones (1967). Recently,
Kwiecinski et al. (2018) studying material from St.
Vincent found that it further clouded the relationship
between these subspecies. They found a tendency for
the St. Vincent material to group with the St. Lucia
material in some measurements, but the St. Vincent
material was intermediate between the values from the
other two islands. They concluded that there was “no
continuing need to recognize the taxon Monophyllus
plethodon luciae Miller 1902 and it should be placed as
a junior synonym of Monophyllus plethodon plethodon
Miller 1900.” This is the taxonomic arrangement fol¬
lowed here.

On St. Lucia, there were no significant differences
in length of forearm and seven cranial measurements
between fourteen males and fourteen females (Table

l) . The averages for length of forearm and maxillary
toothrow were the same for both sexes, averages for
greatest length of skull, condylobasal length, and post¬
orbital constriction were larger in females than males,
and zygomatic breadth, mastoid breath, and breadth
across molars were greater in males than females.

During our study, this species represented 9.4% of
all bat captures on St. Lucia and was captured from near
sea level on the Dennery River (11 m) to our highest
elevation sampled in the Edmund Forest Reserve (550

m) . The species was found in essentially all vegetation
types unless the area was too highly disturbed (Fig.
6). We caught the greatest number of these bats (59
individuals in 11 nets) at the 14,000-ha Quilesse Forest
Reserve (Fig. 7) that was situated above the Roseau
River drainage. This interior plateau was covered in
lower montane rain forest and drier deciduous forest
where we found considerable amounts of fruit on the
ground. In 2008, we placed 11 mist nets at this site with
five placed along a trail above the Forestry Station and
six placed across the entrance road and down a road
leading to the nearby stream. A total of 294 bats were

captured that evening (26.7 BNN), 59 of which were
Monophyllus (20% of all captures at the site). The other
species of bats taken at the site included: A.jamaicensis
x schwartzi (212), S. paulsoni (18), P. davyi (2), M.
molossus (2), and B. cavernarum (1).

The Forestiere Forest Trailhead was at the edge
of the Castries Waterworks Forest Reserve, which was
established in 1916 (Beard 1949). The vegetation at this
netting site was a mix of primary rainforest and lower
montane rainforest, with such trees as candlewood,
bois de masse, balata chien, and bois cote. We set six
nets—two were set along trails into the forest and an
18 m long net was placed at the edge of the parking
lot along the forest edge. The other three nets were
placed in a banana plantation situated just outside of the
Reserve. This was one of three netting sites where we
captured seven species of bats—the highest number of
species from our survey sites on St. Fucia. In addition
to 10 Monophyllus , we netted six other species here:

Figure 6. Map of the geographic distribution of
Monophyllus plethodon on the Lesser Antillean island
of St. Lucia. Symbols include: closed circles represent
specimens examined and open circles represent
literature records.

Pedersen et al.—Bats of Saint Lucia

15

Figure 7. Photograph of the Quilesse Forest Reserve,
Micoud Quarter, St. Lucia, showing the lower montane
rain forest. We captured 59 Monophyllusplethodon in 11
mist nets in a single evening in this area.

P. davyi (1; this was the first specimen of the species
obtained on St. Lucia), B. cavernarum (2), A. nichollsi
(5), A. jamaicensis x schwartzi (66), S. paulsoni (1),
and M. molossus (1).

Clarke (2009) reported that “at Durocher, a mesic
forest site bordered by fruit plantations, mist nets inter¬
cepted a huge flock of these long-tongued bats and in
less than three hours, 128 individuals were captured.”
It was our opinion that this was probably not a huge
“flock” of bats but rather that his mist nets were set
along a flyway between a colony of these bats and their
foraging areas in the fruit plantations below.

On 4 February 1901, H. S. Branch collected 13
Monophyllus on St. Lucia, of which two were males
and 11 were females. Both scrotal males had testes
measuring 5. All females were pregnant carrying
single embryos that averaged 15.2 (13-18) in crown-
rump length. On 16 and 17 March 2009, two females
were collected that were carrying single embryos that
measured 13 and 17 in crown-rump length. Six scrotal
males were taken on these dates, five of the individuals
having testes lengths of 3,3,3,4, and 4. Clarke (2009)
reported two palpably pregnant females were captured
on 26 March and one pregnant female was captured on
1 April. Forty-eight Monophyllus were captured and
examined during our survey between 17 and 20 June

2007, with 39 females and nine males constituting the
sample. The reproductive status of the females was
as follows: 5 pregnant; 8 lactating; 1 post-lactating;
and 25 evinced no gross reproductive activity. One
of the pregnant females was carrying an embryo that
measured 21 in crown-rump length. Five of the males
were scrotal and the other four had testes in an inguinal
position. The scrotal males had testes lengths of 3,4,4,
4, and 4 and one of the non-scrotal males had a testes
length of 2. We examined 101 Monophyllus between
30 July and 4 August 2008, with 55 females and 46
males constituting the sample. The reproductive status
of the females was as follows: 1 pregnant; 26 lactating;
4 post-lactating; 23 evincing no gross reproductive
activity; and 1 subadult. Eight of the males had testes
in a scrotal position and the other 38 had testes in an
inguinal position. One of the scrotal males had a testes
length of 3 and four of the non-scrotal males had testes
lengths of 1, 3, 3, and 3.

Limited data indicate that Monophyllus might be
monoestrous on St. Vincent (Kwiecinski et al. 2018).
On Barbados, Genoways et al. (2011) did not have
sufficient data to understand the entire reproductive
cycle, but their data suggested a bimodal polyestrous
cycle, or alternatively, populations belonging to dif¬
ferent maternity colonies may not be synchronous in
their reproductive cycles and young were produced
over an expanded monoestrous cycle. On Dominica,
Genoways et al. (2001) found that nine of 10 females
were pregnant during the period of late March to late
April, the embryos of which were near-term. Elements
of these reproductive patterns were similar to what
we have observed on St. Lucia—breeding occurred
during the dry season in December and January with
gestation taking place in February, March, and April.
Parturition occurred in late April through early June as
the wet season was beginning. Young bats started to fly
as the wet season was reaching its height in July and
August. However, five pregnant females captured in
mid-June (13% of the females examined) and a preg¬
nant female netted 1 August argue for a second wave
of reproduction. It was unclear if the females had a
postpartum estrus in March and April or if there was
less synchronicity in breeding in Monophyllus than in
many other phyllostomid bats in the region. Certainly,
if there was a postpartum estrus, only a few females
were participating. It appears that less than 10% of

16

Special Publications, Museum of Texas Tech University

the females were pregnant during times when a sec¬
ond birth for the year would be expected. Additional
records of this species through the months of July to
September would be necessary to answer questions
about its reproductive cycle.

Two pregnant females netted in mid-March
weighed 13.2 and 14.5, whereas six scrotal males
from this time had a mean weight of 15.1 (13.7-15.9).
Those Monophyllus taken on St. Lucia in mid-June
had the following weights: five adult females reveal¬
ing no gross reproductive activity, 13.2 (11.8-14.4);
a pregnant female, 16.5; two lactating females, 12.9,
13.4; a post-lactating female, 13.2; five scrotal males,
14.7 (13.8-15.3); two non-scrotal males, 14.0, 14.7.
Monophyllus taken on St. Lucia at the end of July and
early August had the following weights: three adult
females revealing no gross reproductive activity, 12.1,
13.4, 14.3; four lactating females, 12.3, 12.4, 13.7,
14.3; two post-lactating females, 12.7, 14.4; a scrotal
male, 14.4; five non-scrotal males, 14.0 (12.6-15.2).
Although our weight data were not extensive, males
were heavier than females, on average.

Brachyphylla cavernarum cavern arum Gray, 1834
Antillean Fruit-eating Bat

Specimens examined (91).—Castries: Barre de
Lisle Ridge, 0.5 km S, 1.3 km E Rivine Poisson, 294
m [13°55'35.3"N, 60°57'32.0"W], 1 (TTU 109626);
Forestiere Forest Trailhead, 0.5 km S, 0.5 km E For¬
estiere, 300 m [13°58T1.2"N, 60°57'08.8"W], 2 (TTU
109624-25); 1.5 km E Marigot Bay, 4 (UNSM 16489,
16563-65); Marigot Bay, 2 (UNSM 16569-70). Dau¬
phin: Monchy, 25 m [14 o 03'10.7"N, 60°56'03.2"W],
1 (TTU 111043). Dennery: Au Leon Peak, 1 km
N, 1.75 km E La Ressource, 319 m [13°5714.4"N,
60°54'07.1"W], 3 (TTU 111044-46). Laborie: 1.25
km N, 0.75 km E Saltibus, 398 m [13°48'59.8"N,
61°00'21.9"W], 1 (TTU 111047). Micoud: Quilesse
Forest Reserve, 2.5 km N, 8 km W Micoud, 283 m
[13°50'23.1"N, 60°58'25.8"W], 1 (TTU 109627).
Soufriere: Diamond Botanical Garden, Diamond, 47
m [13°51'08.7"N, 61°02'57.5"W], 2 (TTU 111048-19);
Edmund Forest Reserve, 0.7 km N, 1.5 km E Fond
St. Jacques, 550 m [13°50'27.9"N, 60°59'47.6"W],
8 (TTU 109630-37); Soufriere Cave, Soufriere, 0 m
[13°51'29.1"N, 61°03'52.2"W], 2 (TTU 109628-29).

Vieux Fort: Grace Cave, 2.4 kmN, 1 km W Grace, 165
m [13°4757.0"N, 60°58'43.6"W], 8 (TTU 109638-45).
No Specific Quarter: no specific locality, 56 (NMNH
106000-055).

Additional records. —Castries: Castries Wa¬
terworks Reserve, near Forestiere [~ 13°58T3.3"N,
60°56'56.6"W] (Arendt and Anthony 1986). No
Specific Quarter: no specific locality (Miller 1913a;
Koopman 1968; Swanepoel and Genoways 1978).

Specimens captured/released (9).—Castries:
Barre de Lisle Ridge, 0.5 km S, 1.3 km E Rivine Pois¬
son, 294 m [13°55'35.3"N, 60°57'32.0"W], 8. Laborie:
1.25 kmN, 0.75 km E Saltibus, 398 m [13°48'59.8 M N,
61°00'21.9"W], 1.

The genus Brachyphylla is endemic to the Antil¬
les and includes two species (Swanepoel and Genoways
1978). The northern species is B. nana , which occurs
on Cuba, Grand Cayman, Middle Caicos, and Hispan¬
iola. The larger of the two species, B. cavernarum , is
known from Puerto Rico, the Virgin Islands, and the
Lesser Antillean islands as far south as St. Vincent and
Barbados. The members of the nominate subspecies
occur on St. Croix in the Virgin Islands and throughout
the Lesser Antillean islands south to St. Lucia and St.
Vincent. The smaller subspecies, B. c. minor , occurs
on Barbados (Genoways et al. 2011). A third subspe¬
cies, B. c. intermedia , was found on Puerto Rico and
all Virgin Islands except St. Croix (Swanepoel and Ge¬
noways 1978). Although genetic analysis of St. Lucian
B. cavernarum remains to be conducted, Carstens et al.
(2004) reported a lack of mitochondrial DNA genetic
variation in northern Lesser Antillean populations.

In the analysis of 12 cranial measurements pre¬
sented by Swanepoel and Genoways (1978), the mean
values of the St. Lucia population of Brachyphylla
nearly matched those from the type locality of St.
Vincent, except for palatal length of females, where the
differential between the mean values of these two popu¬
lations was 0.3 mm or less. The length of forearm and
seven cranial measurements for fifteen males and four¬
teen females (Table 1) revealed no significant secondary
sexual dimorphism. Average male measurements were
larger for greatest length of skull, condylobasal length,
postorbital constriction, and mastoid breadth, whereas

Pedersen et al.—Bats of Saint Lucia

17

average female measurements were larger for length
of forearm, zygomatic breadth, and breadth across
upper molars. There was no difference between male
and female averages for length of maxillary toothrow.
Swanepoel and Genoways (1978) found males to be
generally larger than females and concluded that there
was sufficient secondary sexual dimorphism to analyze
the sexes separately. This conclusion was not supported
by our data. However, there is significant secondary
sexual dimorphism in the structure of the pelvis, to
the extent that this character was utilized to establish
sex-ratios and determine periodic utilization of a cave
roost by this species at a fossil maternity colony on the
island of Marie Galante (Pelletier et al. 2017).

Ten of our 44 captures of this bat were from
within two caves: Soufriere Cave (2) at sea level and
Grace Cave (8) at 165 m. The remaining 34 individuals
were netted in a variety of foraging areas from 25 m
to 550 m (Fig. 8). Several of these are profiled below.
The amount of insect remains found in the feces of
this omnivorous bat increase substantially during the
early dry season (December-January) on the island of
Guadeloupe (Lenoble et al. 2014a).

Grace Cave (Fig. 9) served as a day roost for a
colony of Brachyphylla. Reaching the cave required
a descent of approximately 50 m down a very steep
ravine from an unpaved road at the ridge top. The
cave was located below a small waterfall on the rock-
strewn ravine floor. The small stream running adjacent
to the cave was thought to be a tributary of the Grande
Riviere du Vieux Fort. Grace Cave was a solution cave
approximately 15 m deep into the ravine wall and about
30 m wide along the stream. The dome of the ceiling
varied from 3 to 5 m high above a mostly dry cobble
floor. Because the colony was disturbed by our entry
in the cave, we were unable to determine the size of
the colony, but only Brachyphylla was observed in
this roost.

We located a second day roost for Brachyphylla
on St. Lucia in a sea cave located on the north side of
the Soufriere Bay. This cave consisted of a tapering
vertical fissure that was 3 to 4 m wide at its base and
extended 14 m upwards. At the time Clarke visited
(March 2009) “this roost consisted of several thousand,
noisy, squabbling Antillean fruit bats, visually esti-

Figure 8. Map of the geographic distribution of
Brachyphylla cavernarum on the Lesser Antillean island
of St. Lucia. Symbols include: closed circles represent
specimens examined and the open circle represents a
literature record.

Figure 9. Photograph of the mouth of Grace Cave, Viex
Fort Quarter, St. Lucia, taken from above on the bank of
the small stream. The cave was occupied by a colony of
Brachyphylla cavernarum.

18

Special Publications, Museum of Texas Tech University

mated at -5,000 individuals, but no other bats species
were observed” (Clarke 2009).

In the Castries Waterworks Reserve, Arendt and
Anthony (1986) located a colony of Brachyphylla in
a large cavity within an acomat boucan tree. They re¬
ported: “Trunk circumference at breast height was 2.82
m. Vertical distance to the cavity was 7.22 m. Cavity
height, width, and inside diameter were 2.74,0.24, and
0.50 m, respectively.” They observed a juvenile St.
Lucia boa ( Boa constrictor orophias ) feeding on the
bats in the colony. A pregnant female bat weighing 67
g and a length of forearm of 63.1 was extracted from
the mouth of the snake.

A sample of Brachyphylla was obtained dur¬
ing the period of 4 January to 10 February 1901 that
included 15 females of which 14 were pregnant and
one showed no gross reproductive activity. The 14
embryos carried by these females were relatively small,
with an average crown-rump length of 8.4 (5-12).
Two scrotal males taken during this time had testes
measuring 6 and 8 in length, whereas 18 males had
testes in an inguinal position and seven of those had
testes lengths that averaged 4.6 (3-6). Two females
captured on 4 March 1901 each carried a single em¬
bryo that measured 6 and 16 in crown-rump length. In
mid-March (14-17), at the depth of the dry season, all
seven females captured were pregnant, with six of the
embryos having a mean crown-rump measurement of
21(18-24). A scrotal male captured during this period
had testes measuring 6 in length. Arendt and Anthony
(1986) reported a pregnant female taken on 20 March
1984, but they give no indication of the size of the
fetus. By the onset of the rainy season in mid-June
(17-20), all nine of the adult females captured were
lactating. Nine adult males captured during this time
were all judged to reproductively inactive, with testes
in a non-scrotal position and measuring an average of
5 (3-6) in length. As the rainy season was approach¬
ing its height, eight adult females were captured one
of which was lactating and the other seven evinced
no gross reproductive activity. The one scrotal male
taken had a testes length of 7, whereas three males with
testes in an inguinal position had lengths of testes of 4,
4, and 6. The female reproductive cycle begins with
breeding early in the dry season (December-January)
and Krutzch and Nellis (2006) found spermatogenesis

in males from September to December on St. Croix.
Gestation would occur from January through April
during the dry season, with parturition at the begin¬
ning of the wet season in May. Our latest record for a
lactating female was 2 August, but some individuals
probably lactate throughout August. There does not
seem to be evidence of a post-partum estrus. We agree
with Krutzch and Nellis (2006; see also Wilson 1973,
1979, and Swanepoel and Genoways 1983) that the
reproductive cycle of B. cavernarum is best described
as synchronous, seasonal monestry.

Six pregnant females taken in March had an aver¬
age weight of43.8 (40.4-49.4), whereas an adult male
from this time weighed 40.9. In mid-June, six lactat¬
ing females had a mean weight of 44.3 (42.1-46.7),
whereas six non-reproductive males weighed an aver¬
age 43.6 (39.4-50.3). A lactating female obtained in
early August weighed 42.0 and five non-reproductive
females had the same mean weight of42.0 (38.4-45.1).
In early August, a scrotal male weighed 47.7 and three
males with testes in an inguinal position weighed 38.6,
45.4, and 45.6. Omitting the pregnant females, it ap¬
pears that the sexes averaged approximately the same
weights.

Sturnira paulsoni luciae Jones and Phillips, 1976
Paulson’s Yellow-shouldered Bat

Specimens examined (31).—Castries: Barre de
Tlsle Ridge, 0.5 km S, 1.3 km E Rivine Poisson, 294
m [13°55'35.3"N, 60°57 , 32.0"W], 3 (TTU 110607-09);
Forestiere Forest Trailhead, 0.5 km S, 0.5 km E For¬
estiere, 300 m [13°58T1.2"N, 60°57'08.8"W], 1 (TTU
110596); 1.5 km E Marigot Bay, 1 (UNSM 16488);
Piton Flore, Forestiere Forest Trail, 1.2 km S, 1.9 km
E Forestiere, 300 m [13°57'51.6"N, 60°56'24.0"W], 2
(TTU 110597-98). Dauphin: 0.5 mi SE Boguis, 100 ft,
7 (KU 110135^11). Gros Islet: Union Agricultural Sta¬
tion, 100 ft, 1 (KU 110134). Laborie: 1.25 kmN, 0.75
km E Saltibus, 398 m [13°48'59.8"N, 61°00'21.9"W],
1 (TTU 113315). Micoud: Quilesse Forest Reserve,
2.5 km N, 8 km W Micoud, 283 m [13°50'23.1"N,
60°58'25.8"W], 8 (TTU 109259-60, 110599-604).
Praslin: Mamiku River, 1.1 km N, 0.2 km E Mon
Repos, 3 m [13°52'02.8"N, 60°54'05.0"W], 1 (TTU
110605); Raillon Negres, 1.2 km N, 2.3 km W Mon
Repos, 255 m [13°52'25.3"N, 60°56'09.6"W], 2 (TTU

Pedersen et al.—Bats of Saint Lucia

109255,110606). Soufriere: Diamond Botanical Gar¬
den, Diamond, 47 m [13°51'08.7"N, 61°02'57.5"W],
1 (TTU 109256). Vieux Fort: Woodlands Estate,
2.25 km N, 1.3 km W Grace, 211 m [13°47'54.7"N,
60°58'50.7"W], 3 (TTU 109257-58, 110610).

Additional records (Clarke 2009, unless noted
otherwise).—Anse La Raye: “Anse La Raye” [=
Venus Estate] [converted from UTM, 13°55T4.7"N,
61 °01T2.1 ,r W]; Millet Forest [= Millet Bird Sanctuary]
[converted from UTM, 13°53'44.7"N, 60°59'50.2"W].
Castries: Barre de Elsie Ridge. Choiseul: River Doree
[converted from UTM, 13°46'05.1"N, 61 o 01'54.6"W].
Micoud: Des Cartier Rainforest Trail [converted
from UTM, 13°50'24.2"N, 60°48'45.9"W]. Praslin:
“Durocher” [= Morne Durocher] [converted from
UTM, 13°52'34.4"N, 60 o 56'12.5 M W]. Soufriere:
Anse Chastanet [converted from UTM, 13°52'00.9"N,
61°04T0.3"W]. No Specific Quarter: no specific
locality (Jones and Phillips 1970).

Specimens captured/released (45).—Castries:
Barre de Elsie Ridge, 0.5 km S, 1.3 km E Rivine
Poisson, 294 m [13°55'35.3"N, 60°57'32.0"W], 15.
Piton Flore, Forestiere Forest Trail, 1.2 km S, 1.9 km
E Forestiere, 300 m [13°57 , 51.6"N, 60°56'24.0"W],
2. Dennery: Au Leon Peak, 1 km N, 1.75 km E La
Ressource, 319 m [13°57T4.4"N, 60°54'07.1"W], 1.
Micoud: Quilesse Forest Reserve, 2.5 km N, 8 km
W Micoud, 283 m [13°50'23.1"N, 60°58'25.8"W],
10. Praslin: Raillon Negres, 1.2 km N, 2.3 km W
Mon Repos, 255 m [13°52'25.3"N, 60°56'09.6"W],
10. Soufriere: Edmund Forest Reserve, 0.7 km N,
1.5 km E Fond St. Jacques, 550 m [13°50'27.9"N,
60°59'47.6"W], 5. Vieux Fort: Woodland Estate,
2.25 km N, 1.3 km W Grace, 211 m [13°4754.7"N,
60°58'50.7"W], 2.

Bats of the genus Sturnira are known from the
Lesser Antilles from Montserrat (Pedersen et al. 1996)
southward to Grenada (Genoways et al. 1998), but they
are absent on Barbados and the Grenadines. Kwiecinski
et al. (2018) recently reviewed the morphological (de la
Torre 1966; de la Torre and Schwartz 1966; Jones and
Phillips 1976; Genoways 1998) and molecular (Velazco
and Patterson 2013) studies of Antillean Sturnira,
which have resulted in major taxonomic changes. The
morphological studies recognized two species occur-

19

ring on the Lesser Antillean islands. The endemic S.
thomasi was restricted to the islands of Guadeloupe
and Montserrat, whereas several subspecies of S.
lilium were found from Dominica southward to South
America. The molecular study conducted by Velazco
and Patterson (2013) resulted in a significantly differ¬
ent taxonomic arrangement with two endemic species
occupying the Lesser Antillean islands. The northern
endemic, S. angeli, was recognized on the islands of
Montserrat, Guadeloupe, Dominica, and Martinique,
whereas S. paulsoni was recognized on St. Lucia,
St. Vincent, and Grenada. Kwiecinski et al. (2018)
reviewed the discordance between the morphological
and molecular data, but they “followed the taxonomy
of the molecular study because it was comprehensive
and most recently conducted.” We have followed this
arrangement herein as well using the scientific name S.
p. luciae for the population on St. Lucia. We recom¬
mend additional genomic studies aimed at examining
recently evolved reproductive and/or genetic isolating
mechanisms in Caribbean Sturnira.

Our analyses of the length of forearm and seven
cranial measurements for 14 male and 10 female Stur¬
nira collected on St. Lucia revealed that males averaged
larger than females for all measurements except length
of maxillary toothrow, which was the same for both
sexes (Table 1). The greatest length of skull and con-
dylobasal length were significantly (P <0.01) larger in
males, but no significant secondary sexual dimorphism
was found in the remaining six measurements.

Five Sturnira were netted while foraging in dry
forest on the Woodland Estate (Fig. 10). This site was
along a ridge top above the coastal lowlands of southern
St. Lucia. Native trees were bearing small fruits (18
June 2007) many of which were evident on the ground.
Nets were placed across the Estate road, at the head
of ravines intersecting the road, and around a stand of
pepper plants. Only two other species were captured
at this site— M. plethodon (4) and A. jamaicensis x
schwartzi (34).

It was interesting to compare two sites that we
worked on the successive nights of 29 and 30 July 2008
in the Quarter of Praslin. The Mamiku River site was
the lowest elevation (3 m) where we caught Sturnira.
The original vegetation in the area would have been dry

20

Special Publications, Museum of Texas Tech University

Figure 10. Map of the geographic distribution of
Sturnira paulsoni on the Lesser Antillean island of
St. Lucia. Symbols include: closed circles represent
specimens examined and open circles represent
literature records.

lowland scrub woodland, but much of this vegetation
had been replaced by various buildings, a small resort,
small banana plantations, ornamental plantings, a small
botanical garden (Mamiku Garden), fruit trees such as
guava, guinep, soursop, almond, and mango, and low
brushy secondary forest trees. Some of the trees in
Mamiku Garden that could be of value to bats include
bay leaf, white cedar, and buttercup tree. A single net
was placed across a large pond in the riverbed. Bat
activity was quite low at this site. In addition to our
capture of a single Sturnira , two other species of bat
were netted at this site including A. jamaicensis x
schwartzi (9), and M. molossus (3). About 5 km west
of the Mamiku River location we netted at a much
higher elevation (255 m) in lower montane rainforest
near Raillon Negres. This habitat included common
trees such as bois de masse, balata chien, candlewood,
and bois cote. Forest edge species included pepper
plant, gumtree, and bwa kannon. We netted 12 Sturnira
in five mist nets that we had placed across the access
road and in the adjacent forest. We netted Sturnira at

elevations ranging from 3 to 550 m, however, 57 of
the 68 captures (84%) were netted in a narrow band
of elevations (200-300 m), and 95% of captures were
above 200 m. This distribution coincides with that
of wet/moist forests and their associated foraging op¬
portunities located in the interior of the island. Four
other species of bats were netted near Raillon Negres,
including P. davyi (1), M. plethodon (7), A. jamaicensis
x schwartzi (67), and M. molossus (1).

The Edmund Forest Reserve (Fig. 11) was the
highest elevation site that we worked. Beard (1949)
classified the vegetation in this reserve as secondary
rainforest. On 1 August 2008, seven mist nets were lo¬
cated near the top of the forest road where it intersected
with the access road to a radio tower. Many ornamental
plants and cultivated fruit trees were associated with
a building about 300 m below the intersection. Two
additional nets were placed along what remained of
a colonial era road that ascended the ridge before
descending to the Caribbean side of the island. Of
interest, this was one of the three sites where we netted
seven of the nine species known from the island: B.
cavernarum, P. davyi, M. plethodon, A. jamaicensis x
schwartzi, S. paulsoni, M. molossus, and T. brasilien-
sis. If we include the Noctilio and Ardops captured by
Clarke (2009) on the Des Cartier Rainforest Trail, all
nine species of bat from the island were found within
the Edmund Forest Reserve.

Figure 11. Photograph of the Edmund Forest Reserve,
Soufriere Quarter, St. Lucia. The nine known species
of bats occurring on St. Lucia were taken in this forest
reserve.

Pedersen et al.—Bats of Saint Lucia

21

Between 15 and 17 March 2009, three Sturnira
were captured, of which two were females—one was
pregnant with an embryo that was 4 in crown-rump
length and the other revealed no gross reproductive
activity. The scrotal male had testes that measured 6 in
length. A female taken on 24 May 1987 was lactating.
In mid-June 2007 (17 to 20), 10 females were netted of
which seven were lactating, two were pregnant, with
one embryo measuring 8 in crown-rump length, and
one was post-lactating. Three males had testes length
measurements of 2, 5, and 8, with the former being a
subadult having testes in an inguinal position. During
the peak of the rainy season in late July-early August,
23 females evinced no gross reproductive activity, eight
were pregnant, with three of the embryos measuring
17,22, and 24 in crown-rump length, and three females
were lactating. Sixteen males were obtained during this
period, with three having testes in scrotal position (one
testes length of 6), and 13 with testes in inguinal posi¬
tion, average testes length of five individuals, 2.8 (2^4).
A small sample of Sturnira was taken in the period of
26 to 28 August 1967. Three females were included
in the sample with two pregnant carrying embryos that
measured 24 and 26 in crown-rump length and the third
lactating. Five scrotal males had testes that averaged
5.6 (4-7) in length.

Wilson (1979) believed that mainland populations
of Sturnira followed a bimodal polyestrous reproduc¬
tive cycle. Our data from St. Lucia would appear to fit
this pattern. Our March sample was very small, but it
did include one pregnant female. Most females had un¬
dergone parturition before our work in mid-June, with
70% of the females lactating, but two were pregnant,
which we believe was the result of a postpartum estrus.
During the rainy season in July and early August, eight
females were pregnant and three were lactating, but
about 67% of females showed no gross reproductive
activity so the postpartum breeding did not include the
entire population. Although the late August data for
females was limited, they were still reproducing at that
time. Most males at beginning of August appeared to
be reproductively inactive, but the males in the late
August sample appeared to be ready for sexual activity.

On St. Lucia, a pregnant female weighed 16.2, a
non-pregnant female weighed 19.4, and a scrotal male
weighed 19.6 when captured between 15 to 17 March

2009. Two pregnant females weighed 19.0 and 25.2,
seven lactating females had a mean weight of 18.0
(16.6-21.1), one post-lactating female had a weight
of 20.0, and two scrotal males weighed 21.2 and 23.0
when netted 17 to 20 June 2007. From 30 July to 4
August 2008, nine non-reproductive females had a
mean weight of 19.2 (17.8-22.7), a lactating female
had a weight of 21.2, and five pregnant females had an
average weight of22.2 (20.5-24.5). Weights of males
from this time period were 18.3 for a scrotal male with
weights of 16.2,18.2,18.4, and 18.4 for four males with
testes in a non-scrotal position. These data indicate that
there was little difference in the weights of males and
females when pregnant females were excluded from
consideration.

Artibeus jamaicensis x schwartzi

Jamaican Fruit-eating Bat (hybrid)

Specimens examined (242).—Anse La Raye:
Anse La Raye; 1 m [13°56'30.3"N, 61°02'28.2"W],
8 (TTU 109409-16). Castries: Barre de Lisle
Ridge, 0.5 km S, 1.3 km E Rivine Poisson, 294 m
[13°55'35.3"N, 60°57 , 32.0 ,, W], 11 (TTU 109209-10,
109248, 109440-44, 109518-20); Cul de Sac River,
south bank, west slope of Barre de Lisle Ridge [prob¬
ably near Deglos at ~13°58'29.14"N, 60°58'36.0"W],
2 (AMNH 239588-89); Forestiere Forest Trailhead,
0.5 km S, 0.5 km E Forestiere, 300 m [13°58T1.2"N,
60°57'08.8"W], 4 (TTU 109434-37); Piton Flore, For¬
estiere Forest Trail, 1.2 km S, 1.9 km E Forestiere, 300
m [13°57'51.6"N, 60°56'24.0"W], 2 (TTU 109438-39);
1.5 km E Marigot Bay, 26 (UNSM 16490-92, 16540-
62); Marigot Bay, 36 (UNSM 16720-29,16731-49,
16782-88); Union Nature Trail, 0.6 km N, 0.5 km W
Balata, 18 m [14°0L14.2"N, 60°57'41.8"W], 24 (TTU
109205-06, 109237-41, 109417-33). Dauphin:
Monchy, 25 m [14°03T0.7"N, 60°56'03.2"W], 5 (TTU
110989-93); Ruins of Marquis Estate, 1.6 kmN, 0.8
km E Boguis, 25 m [14°0L35.2"N, 60°54'40.6"W], 6
(TTU 109207-08,109242^43,109445^46). Dennery:
Au Leon Peak, 1 kmN, 1.75 km E La Ressource, 319
m [13°57T4.4"N, 60 o 54'07.1"W], 8 (TTU 110941-48);
Dennery River, 0.25 km S, 2 km W Dennery, 11m
[13°54'34.6"N, 60°54T6.2"W], 4 (TTU 109447-50).
Gros Islet: Union Agriculture Station, 100 ft, 13 (KU
110159-69, 110172-73). Laborie: 1.25 kmN, 0.75
km E Saltibus, 398 m [13°48'59.8"N, 61°00 , 21.9 ,, W],

22

Special Publications, Museum of Texas Tech University

2 (TTU 110949-50). Micoud: Canelles River, 1.5 km
S Anse Ger, 10 m [13°46'59.6"N, 60°54'53.1"W], 12
(TTU 109474-85); Quilesse Forest Reserve, 2.5 kmN,
8 km W Micoud, 283 m [13°50'23.1"N, 60°58'25.8"W],
13 (TTU 109461-73); Troumassee River, 1.3 km W
Micoud, 40 m [13°49T3.9"N, 60°54'53.7"W], 10 (TTU
109451-60). Praslin: Fox Grove Inn, LI kmN, 0.2 km
WMon Repos, 52 m [13°5F47.0"N, 60°54'22.8"W], 13
(TTU 109486-98); Mamiku River, 1.1 km N, 0.2 km
E Mon Repos, 3 m [13°52'02.8"N, 60°54'05.0"W], 9
(TTU 109499-507); RaillonNegres, 1.2 kmN, 2.3 km
W Mon Repos, 255 m [13°52'25.3"N, 60°56'09.6"W],
10 (TTU 109509-17, 116545). Soufriere: Diamond
Botanical Garden, Diamond, 47 m [13°5F08.7"N,
61°02'57.5"W], 5 (TTU 110951-55); Edmund Forest
Reserve, 0.7 kmN, 1.5 km E Fond St. Jacques, 550 m
[13°50'27.9"N, 60°59'47.6"W], 12 (TTU 109521-32).
Vieux Fort: Woodland Estate, 2.25 km N, 1.3 km W
Grace, 211 m [13°4754.7 M N, 60°58'50.7"W], 6 (TTU
109244-47, 109533-34). No Specific Quarter: no
specific locality, 1 (NMNH 106014).

Additional records (Clarke 2009, unless other¬
wise noted).— Anse La Raye: “Anse La Raye” [=
Venus Estate] [converted from UTM, 13°55T4.7"N,
61 °0 F12.1"W]; Millet Forest [= Millet Bird Sanctuary]
[converted from UTM, 13 0 53'44.7 M N, 60°59'50.2"W].
Castries: Barre de Lisle Ridge, 0.5 km S, 1.3 km E
Rivine Poisson, 294 m [13°55'35.3"N, 60°5732.0"W].
Choiseul: River Doree [converted from UTM,
13°46'05.1"N, 61°01'54.6"W], Dauphin: Sor-
ciere River [converted from UTM, 14°0F26.6"N,
60°54'33.2"W]. Laborie: near Piaye [converted
from UTM, 13°46 , 05.1"N, 61°0F54.6"W]. Micoud:
Des Cartier Rainforest Trail [converted from UTM,
13°50'24.2"N, 60°48'45.9"W], Praslin: “Durocher" [=
Mome Durocher] [converted IfomUTM, 13°52'34.4"N,
60°56T2.5"W], Soufriere: Edmund Forest Reserve.
No Specific Quarter: no specific locality (Koopman
1968; Jones and Phillips 1970; Jones 1978).

Specimens captured/released (791).— Castries:
Barre de Elsie Ridge, 0.5 km S, 1.3 km E Rivine
Poisson, 294 m [13°55'35.3"N, 60°57'32.0"W], 118;
Forestiere Forest Trailhead, 0.5 km S, 0.5 km E For¬
estiere, 300 m [13°58'11.2"N, 60°57'08.8"W], 62;
Piton Flore, Forestiere Forest Trail, L2 km S, 1.9 km
E Forestiere, 300 m [13°5751.6 M N, 60°56'24.0"W],

22; Union Nature Trail, 0.6 km N, 0.5 km W Balata,
18 m [14°01T4.2"N, 60°5741.8"W], 90. Dauphin:
Monchy, 25 m [14°03'10.7 M N, 60 o 56'03.2"W], 34;
Ruins of Marquis Estate, L6 km N, 0.8 km E Boguis,
25 m [14°01'35.2"N, 60°54'40.6"W], 12. Dennery:
Au Leon Peak, 1 kmN, L75 km E La Ressource, 319
m [13°57T4.4"N, 60°54 , 07.E , W], 10; Dennery River,
0.25 km S, 2 km W Dennery, 11 m [13°54'34.6"N,
60°54'16.2"W], 23. Laborie: 1.25 km N, 0.75 km
E Saltibus, 398 m [13°48'59.8"N, 61°00 , 21.9"W],
1. Micoud: Canelles River, 1.5 km S Anse Ger,
10 m [13°46'59.6"N, 60°54'53.1"W], 10; Quilesse
Forest Reserve, 2.5 km N, 8 km W Micoud, 283
m [13°50'23.1"N, 60°58'25.8"W], 199; Troumas¬
see River, 1.3 km W Micoud, 40 m [13°49T3.9"N,
60°54'53.7"W], 73. Praslin: Fox Grove Inn, 1.1
km N, 0.2 km W Mon Repos, 52 m [13°51'47.0"N,
60°54'22.8"W], 5; RaillonNegres, 1.2 kmN, 2.3 km W
Mon Repos, 255 m [13°52'25.3"N, 60°56'09.6"W], 57.
Soufriere: Diamond Botanical Garden, Diamond, 47
m [13°51'08.7"N, 61°02'57.5"W], 33; Edmund Forest
Reserve, 0.7 km N, 1.5 km E Fond St. Jacques, 550
m [13°50'27.9"N, 60°59'47.6"W], 14. Vieux Fort:
Woodland Estate, 2.25 kmN, 1.3 km W Grace, 211m
[13°4754.7"N, 60°58'50.7"W], 28.

The St. Lucian population of Artibeus resides at
the northern edge of a remarkable hybrid zone involv¬
ing three species, A.jamaicensis, A. planirostris , and A.
schwartzi (P. Larsen et al. 2010; also see A. schwartzi
species account in Kwiecinski et al. 2018). This hy¬
brid zone likely formed within the last -15,000 years
and was the result of primary contact among multiple
genetic lineages of Artibeus that converged in the
southern Lesser Antilles. Phillips et al. (1989, 1991)
and Pumo et al. (1988, 1996) identified the presence
of both A.jamaicensis and A. schwartzi mitochondrial
haplotypes within the St. Lucian population of Artibeus.
The most recent genetic and morphological data from
St. Lucian specimens of Artibeus (n = 17) was pre¬
sented in P. Larsen et al. (2010) and these data consist
of AFLPs, mitochondrial DNA sequence data, and 17
cranial and mandibular measurements. Collectively,
these data indicated the presence of sympatric pheno¬
types of A. jamaicensis and A. schwartzi on St. Lucia
as well as putative FI and F2 hybrids. Nevertheless,
the majority of specimens collected from St. Lucia
exhibit morphological characteristics that are typical of

Pedersen et al.—Bats of Saint Lucia

A. jamaicensis (see below). When considering active
hybridization between A. jamaicensis and A. schwartzi
(as hypothesized by Larsen et al. 2010), we posit that
A. jamaicensis x schwartzi is the most appropriate
taxonomic assignment for St. Lucian Artibeus, pending
additional genomic and morphometric data.

The length of forearm and seven cranial mea¬
surements for 10 males and 14 females (Table 1) of
these hybrid Artibeus revealed no sexual secondary
dimorphism in the St. Lucia population. Average
measurements for males were greater for greatest
length of skull and postorbital constriction, average
measurements for females were greater for length of
forearm, condylobasal length, and breadth across up¬
per molars, and average measurements were the same
for zygomatic breadth, mastoid breadth, and length of
maxillary toothrow.

Genoways et al. (2010) reviewed data concern¬
ing variation in the presence/absence of the upper M3
and lower m3 in Antillean populations of Artibeus but
lacked information for those from St. Lucia. They con¬
cluded that the presence/absence of the upper M3 was
a species-level character, whereas presence/absence
of the lower m3 in this Artibeus complex was neither
an indication of geographic variation nor a species-
level character, but rather it was a low occurrence
polymorphism. We examined 24 individuals from St.
Lucia finding all lacking the upper M3. Populations of
Artibeus from the Bahamas through the Greater Antilles
and south at least far as Dominica in the Lesser Antilles
to which we would now apply the name A. jamaicensis
uniformly lacked the upper third molars. Populations
on Trinidad are considered to be A. planirostris and
100% of the individuals examined have the upper M3
present. In the Grenada population, 89% of the individ¬
uals have the upper M3 indicating a strong relationship
with A. planirostris , but also suggesting some genetic
introgression from A. jamaicensis. Further north in the
Grenadine Islands the overall rate of occurrence of the
upper M3 was only 3.6%, but the rate of occurrence of
the upper M3 was higher again on St. Vincent (11.6%),
associating a low rate of occurrence of M3 with A.
schwartzi. This places the population on St. Lucia with
the characteristics of A. jamaicensis , which lies to the
north. We do not have data for Martinique populations,
but on the next island to the north, Dominica, 100%

23

of 97 individuals examined lacked the upper M3 (Ge¬
noways et al. 2010). This makes the population on St.
Lucia the second along with Barbados (Genoways et
al. 2010, 2011) in which molecular data would place
them with a relationship with A. schwartzi (Pumo et al.
1988, 1996; P. Larsen 2007, 2010), whereas the upper
M3 findings indicate a relationship with A. jamaicensis.
We also examined these 24 individuals for the occur¬
rence of the lower m3, finding that 21 had both lower
m3 present, two were missing both lower m3, and one
individual was missing the left lower m3 (counted as
an absence). This gives a result of 87.5% presence or
12.5% absence of the m3 in the St. Lucia population,
which was a high rate for this polymorphism, matched
or exceeded only by populations on Antigua, Barbuda,
and St. Kitts (Genoways et al. 2010).

These hybrid Artibeus were the most commonly
caught species during our 1987-2009 survey efforts,
representing 65% of all captures. These bats were
captured at all localities where nets were set, from 3
m (Mamiku River) to 550 m (Edmund Forest Reserve)
(Fig. 12). The abundance of this species cannot be
understated—of the 294 bats snared in 11 nets set at
Quilesse Forest Reserve, 212 were Artibeus (72%, 19.3
Artibeus per net), the greatest number of this species
caught at a single location during our work.

On the first night of our 2007 (14 June) field
season we caught 114 Artibeus and nine Molossus near
the headquarters of the Forestry Department, Ministry
of Agriculture, near Balata. We set three nets in the
channel of the Choc River where there were standing
pools of water. Six other nets were set along the Union
Nature Trail including an area containing mango trees.
The original vegetation in this area was lowland dry
scrub woodland, but it has mostly been removed as the
city of Castries has advanced in this direction.

We netted at two sites near Marigot Bay on the
nights of 24-25 May 1987, during studies focusing
on the genetics of this Artibeus complex (Pumo et al.
1988,1996; Phillips etal. 1989,1991). We obtained 26
individuals of Artibeus on the first night east of Marigot
Bay and 36 the next night in the resort area adjacent to
the bay. The general vegetation in the area was typical
lowland dry scrub woodland. East of Marigot Bay, we
set four nets in and around a banana plantation and the

24

Special Publications, Museum of Texas Tech University

Figure 12. Map of the geographic distribution of
Artibeus jamaicensis x schwartzi on the Lesser
Antillean island of St. Lucia. Symbols include: closed
circles represent specimens examined and open circles
represent literature records.

adjacent woodland. In the settlement of Marigot Bay,
ornamental and fruit trees were very common, includ¬
ing those that could be used by bats such as mango,
nutmeg, coconut, almond, and soursop. Four nets were
placed within resort grounds in association with mango
and almond trees. Four other species of bats were taken
at these related sites: B. cavernarum at both sites, S.
paulsoni at the east Marigot Bay site, and M. plethodon
and M. molossus at the bay only.

We collected 83 Artibeus on the night of 30 July
2008 along the Troumassee River near Micoud. The
lowland dry scrub woodland in this area had been heav¬
ily impacted by land clearing and the development of
commercial banana plantations. Five nets were placed
within a dense banana plantation and across the Trou¬
massee River, the banks of which were badly eroded,
with tree roots protruding from the banks. Most of
the Artibeus were netted in the plantation along with
a single M. plethodon. Over the river, we caught M.
molossus (40) and T. brasiliensis (1).

Clarke (2009) reported that on the 19 February,
two females were taken that appeared to be in an early
stage of pregnancy, and three “late stage” palpably
pregnant females were captured on 1 April (2) and 7
April (1). We have collected extensive reproductive
data for this species—14 to 17 March 2009, during the
dry season; 24 to 26 May 1987; 17 to 20 June 2007,
as the rainy season was getting underway; and 30 July
to 4 August 2008, as the rainy season was moving
toward its height. Pregnant females were collected in
each of these survey periods. In the dry season sample
from March, a third (20 of 63) of the females were
pregnant, with the remaining 43 females revealing
no gross reproductive activity. Seven of the embryos
had a mean crown-rump length of 26.1 (15-40), with
the largest embryo having a forearm length of 24 and
a weight of 10.9. It was noteworthy that no lactating
or post-lactating adults or subadults (male or female)
were present during this period. This suggests that there
must have been a suspension of reproductive activity
by these bats earlier in the dry season possibly as early
as November and December.

As the dry season was ending and the rain was
coming on in late May, over 59% (10 of 17) of the
females were pregnant, with embryos that averaged
17.7 (7-32) in crown-rump length. One of the pregnant
females with a 9 crown-rump length embryo was also
lactating, indicating to us that at least some of females
were undergoing a postpartum estrus and breeding. Of
the seven remaining females, two were lactating and
five revealed no gross reproductive activity.

During June, over 85% of the adult females (148
of 173) examined were pregnant. Fifteen of these em¬
bryos averaged 21.9 (6-33) in crown-rump length. Of
the remaining adults, 17 were lactating, one was post-
lactating, and seven revealed no reproductive activity.
We also netted 40 subadult females during this time
frame. These bats were fully engaged in reproductive
activity by the early rainy season in June. However, the
presence of volant subadults and the observation that
4% of the netted individuals were not reproductively
active suggests that at least one cohort of young had
been produced before June.

As the rainy season was reaching its peak in late
July and the beginning of August these bats seem to
be scaling back on reproductive activity. Only 16%

Pedersen et al.—Bats of Saint Lucia

25

of the adult females were pregnant (39 of 258), while
over 57% (148 of 258) evinced no gross reproductive
activity. Two of the embryos of the pregnant females
measured 7 and 29, with the male embryo of the latter
bat having a length of forearm of 12. The remaining
adult females were lactating (51), post-lactating (18),
and post-lactating and pregnant (2). One of the latter
embryos was 16 in crown-rump length. The sample
also included five female subadults and one neonate.
Although breeding had clearly slowed, births have been
recorded in August and lactating females have been
found in August and September.

The majority of the adult males had testes in a
scrotal position and were prepared for breeding in each
of our survey periods—March, 87.5% (21 of 24); May,
58% (7 of 12); June, 96% (73 of 76); and July-August,
84% (192 of229). Testes lengths of four scrotal males
taken in March were 9, 10, 10, and 11; mean testes
lengths of seven scrotal males taken in May were 7.2
(6-9.5) and of five non-scrotal males was 5.6 (5-6);
mean testes lengths of 20 scrotal males taken in June
was 8.1 (6-10); and mean testes lengths of 38 scrotal
males taken in July-August was 9.2 (3-14) and of seven
non-scrotal males was 3.7 (3-5).

A collection of these bats taken on 26 August
1967 is housed the University of Kansas. Included in
this material are seven adult females that exhibited no
gross reproductive activity. Six scrotal males in this
sample had a mean length of testes of 9.5 (5-13).

Studies beginning with those of Wilson (1979)
and Wilson et al. (1991) characterized the reproduc¬
tive cycle of A.jamaicensis as bimodal polyestry. Our
studies on Barbados (Genoways et al. 2011), Dominica
(Genoways et al. 2001), Grenada (Genoways et al.
1998), and the Grenadines (Genoways et al. 2010)
indicate that Artibeus, through this hybrid zone, exhibit
a similar bimodal polyestry. Although it was difficult
to parse out the exact peaks of the bimodal cycle in our
data from St. Lucia, these bats clearly were engaged in
a high rate of reproduction, with most females produc¬
ing at least two young per year.

The mean weight of 24 non-pregnant females
taken in March was 42.6 (34.7-53.3), whereas 12
pregnant females taken at this time had an average

weight of 49.1 (38.2-60.9). The mean weight of 16
scrotal males from March was 40.1 (34.8^19.8) and
three non-scrotal males had weights of 38.2,41.7, and
45.5. The following weights were recorded for bats
captured during June: non-pregnant females, 33.7,
34.4; 16 pregnant females, 48.0 (39.8-60.9); lactat¬
ing females, 43.1, 45.6, 48.2; post-lactating female,
38.7; subadult females, 37.2, 42.5; 20 scrotal males,
40.1 (34.1-43.7); non-scrotal male, 36.4; and subadult
males, 29.4, 32.3, 36.7. The following weights were
recorded for bats captured during July-August: 14 non¬
pregnant females, 38.4 (33.0-43.2); pregnant females,
46.8,49.0; pregnant/post-lactating females, 44.3,54.4;
24 lactating females, 42.4 (35.6-46.5); post-lactating
females, 35.6,38.6,41.5,41.8; subadult females, 34.7,
34.9, 42.0; 39 scrotal males, 40.4 (34.7-48.0); seven
non-scrotal males, 38.2 (34.5-41.2); and subadult
males, 27.6,30.3. Excluding the pregnant females and
subadults, there seems to be no consistent difference
between the weights of the sexes.

No gross abnormalities were observed in any of
these bats, however, three had well-defined patches
of white hair on a shoulder (Barre de Lisle Ridge and
Mamiku River, 2008) or on the rump (Union Nature
Trail, 2007).

Ardops nichollsi luciae (Miller, 1902)
Antillean Tree Bat

Specimens examined (25).—Castries: Barre de
Lisle Ridge, 0.5 km S, 1.3 km E Rivine Poisson, 294 m
[13°55'35.3"N, 60°57'32.0"W], 11 (TTU 109288-98);
Forestiere Forest Trailhead, 0.5 km S, 0.5 km E For¬
estiere, 300 m [13°58T1.2"N, 60°57'08.8"W], 4 (TTU
109281-84); Piton Flore, Forestiere Forest Trail, 1.2
km S, 1.9 km E Forestiere, 300 m [13°5751.6"N,
60°56'24.0"W], 3 (TTU 109285-87). Dennery: Au
Feon Peak, 1 km N, 1.75 km E Fa Ressource, 319 m
[13°57T4.4"N, 60°54'07.1"W], 3 (TTU 110932-34).
No Specific Quarter: no specific locality, 4 (NMNH
110917-20).

Additional records (Clarke 2009, unless other¬
wise noted).—Anse La Raye: Millet Forest [= Millet
Bird Sanctuary] [converted from UTM, 13°53'44.7"N,
60°59'50.2"W], Castries: Barre de Lisle Ridge, 0.5
km S, 1.3 km E Rivine Poisson, 294 m [13°55'35.3 M N,

26

Special Publications, Museum of Texas Tech University

60°57'32.0"W]. Micoud: Des Cartier Rainforest Trail
[converted from UTM, 13°50'24.2"N, 60°48'45.9W].
No Specific Quarter: no specific locality (Miller 1902;
Allen 1911; Jones and Schwartz 1967).

Specimens captured/released (4).—Castries:
Barre de ITsle Ridge, 0.5 km S, 1.3 km E Rivine Pois¬
son, 294 m [13°55'35.3"N, 60°57'32.0"W], 1; For¬
estiere Forest Trailhead, 0.5 km S, 0.5 km E Forestiere,
300 m [13°58'H.2"N, 60°57'08.8"W], 1; Piton Flore,
Forestiere Forest Trail, 1.2 km S, 1.9 km E Forestiere,
300 m [13°57'51.6"N, 60°56'24.0"W], 1. Dennery:
Au Feon Peak, 1 km N, 1.75 km E Fa Ressource, 319
m [13°57T4.4"N, 60°54'07.1"W], 1.

Previously, Jones and Schwartz (1967) recog¬
nized five subspecies of Ardops nichollsi , where the
subspecies luciae was comprised of specimens from
St. Fucia and St. Vincent. In the most recent molecular
and morphological analysis of Ardops, R. Farsen et al.
(2017) found statistical support in a cyt -b phylogeny
for a sister relationship between St. Fucia and St.
Vincent populations. However, those Ardops on St.
Fucia (A. n. luciae ) had unique cyt-b haplotypes that
differed from all other Ardops. These data also pro¬
vided evidence of a new subspecies from St. Vincent
(A. n. vincentensis). Their AFFP data supported the
later by identifying separate island-clades of Ardops
from St. Fucia and St. Vincent (R. Farsen et al. 2017).
Morphologically, specimens from St. Fucia had sig¬
nificantly larger cranial measurements than those from
St. Vincent and were more similar in size to specimens
from the northern islands (A. n. montserratensis, St.
Martin through Guadeloupe). Together these findings
provided strong support for the subspecies luciae on St.
Fucia. The size of the Pleistocene island banks (Rojas
et al. 2011; Baker et al. 2012) could have contributed
to gene flow among populations of A. nichollsi in the
northern Fesser Antilles but may have limited gene
flow in populations distributed in the southern Fesser
Antilles (St. Fucia and St. Vincent). In a 40,000-year
fossil record on the small island of Marie Galante in
the central Fesser Antilles, A. nichollsi does not appear
until the Pleistocene-Holocene transition about 15,000
years ago (McCarthy and Henderson 1992; Stoetzel
et al. 2016).

Table 1 presents length of forearm and seven cra¬
nial measurements for six male and 15 female Ardops

from St. Fucia. There was considerable secondary
sexual dimorphism in these bats on St. Fucia, as we
have found in many other islands in the Fesser Antilles
(Baker et al. 1978; Genoways et al. 2001; Kwiecinski
et al. 2018). Females averaged larger than the males
in all eight measurements. These differences were
significant at P < 0.05 level for four measurements
(length of forearm, greatest length of skull, mastoid
breadth, and breadth across upper molars) and at the P
< 0.001 level for condylobasal length. The remaining
three measurements (zygomatic breadth, postorbital
constriction, and length of maxillary toothrow) did not
test to be significantly different.

If we combine our capture data (2007-2009) with
that of Clarke (2009), 41 of the 42 Ardops captured were
netted at six locations within a very narrow range of
elevations, 294-319 meters (Fig. 2).

We captured four Ardops at Piton Flore on the
Forestiere Forest Trail where it passes through an area
of old secondary rainforest in the Castries Waterworks
Forest Reserve. Some of the larger trees in this area
were maho kockon, candlewood, bois de mass, bois
cote, bitterwood, lansan, and swizzlestick tree. Five
mist nets were set in this area of which two were placed
across the trail, two in a ghut that intersected the trail,
and one near the edge of the forest. Three other species
taken here include M. plethodon (1), A. jamaicensis x
schwartzi (24), and S. paulsoni (4).

Three females taken on 4 January 1901 (2) and 20
January 1901 (1) evinced no gross reproductive activity.
A male collected on 4 February 1901 had testes in an
inguinal position. On 17 March 2009, during the height
of the dry season, we captured four Ardops of which
one was pregnant with an embryo that measured 8 in
crown-rump length and a second female revealed no
gross reproductive activity. The two males taken on
this evening had testes that measured 4 and 6 in length.
A total of 14 Ardops were captured between 17 and 20
June 2007, which was a transition period from the dry
season to the wet season on St. Fucia. Three females
were obtained during this period—one was lactating,
one was post-lactating, and one appeared to be repro-
ductively inactive. Four scrotal males had a mean testes
length of 5.6 (5.0-6.0), whereas four males had testes
in an inguinal position, with lengths of 4, 4, 4, and
5. Seven males were netted on the night of 4 August

Pedersen et al.—Bats of Saint Lucia

2008, of which four had testes in scrotal position with
length measurements of 4, 4, 4, and 5, whereas in the
other three non-scrotal males two measured 3 and 5 in
length. These reproductive data are inadequate for any
comments on the reproductive cycle of Ardops, but the
data were consistent with a bimodal polyestrous cycle
proposed by Kwiecinski et al. (2018) for populations
on St. Vincent.

A non-reproductive female taken in March
weighed 17.1, whereas a pregnant female from this
month weighed 20.5. Two males from March weighed
16.6 and 19.1. Three females taken in mid-June had
the following weights: 19.1 (not reproductively active);
19.8 (lactating); and 22.0 (post-lactating). Eleven
males taken in mid-June had a mean weight of 19.2
(17.5-21.4), whereas six males netted in early August
had an average weight of 18.6 (17.9-19.9).

Family Molossidae

Molossus molossus molossus (Pallas, 1776)

Pallas’s Mastiff Bat

Specimens examined (61).—Castries: Castries,
25 ft, 1 (KU 110263); Forestiere Forest Trailhead,
0.5 km S, 0.5 km E Forestiere, 300 m [13°58T1.2"N,
60°57'08.8"W], 1 (TTU 109927); Marigot Bay, 2
(UNSM 16566-67); Union Nature Trail, 0.6 km N,
0.5kmWBalata, 18 m [14°01T4.2"N, 60°57'41.8"W],
9 (TTU 109918-109926). Dauphin: Ruins of
Marquis Estate, 1.6 km N, 0.8 km E Boguis, 25 m
[14°0T35.2"N, 60°54'40.6"W], 1 (TTU 109928); Mon-
chy, 25 m [14 o 03'10.7"N, 60°56'03.2"W], 4 (TTU
111450-53). Dennery:AuFeonPeak, lkmN, 1.75km
EFaRessource, 319 m [13°57T4.4"N, 60°54 , 07.1"W],
1 (TTU 111454); Dennery River, 0.25 km S, 2 km W
Dennery, 11 m [13°54'34.6"N, 60°54'16.2"W], 15
(TTU 109929-43). Laborie: 1.25 km N, 0.75 km
E Saltibus, 398 m [13°48'59.8"N, 61°00'21.9"W], 1
(TTU 111455). Micoud: Canelles River, 1.5 km S
Anse Ger, 10 m [13°46'59.6"N, 60°54'53.1 "W], 8 (TTU
109948-55); Quilesse Forest Reserve, 2.5 km N, 8
km WMicoud, 283 m [13°50'23.1"N, 60°58'25.8"W],
1 (TTU 109947); Troumassee River, 1.3 km W Mi¬
coud, 40 m [13°49T3.9"N, 60°54'53.7"W], 3 (TTU
109944-46). Praslin: Mamiku River, 1.1 km N, 0.2
km E Mon Repos, 3 m [13°52'02.8"N, 60°54'05.0"W],
3 (TTU 109956-58); RaillonNegres, 1.2 kmN, 2.3 km

27

W Mon Repos, 255 m [13°52'25.3"N, 60°56'09.6"W],

I (TTU 109959). Soufriere: Diamond Botanical Gar¬
den, Diamond, 47 m [13°5r08.7"N, 61°02'57.5"W],
4 (TTU 111456-59); Edmund Forest Reserve, 0.7 km
N, 1.5 km E Fond St. Jacques, 550 m [13°50'27.9"N,
60°59'47.6"W], 4 (TTU 109960-63). Vieux Fort:
Black Bay, 2.5 mi W Vieux Fort, 100 m [13°44'36.0"N,
60°58'55.5"W], 1 (NMNH 514481). No Specific
Quarter: no specific locality, 1 (NMNH 110924).

Additional records (Clarke 2009, unless other¬
wise noted).—Anse La Raye: “Anse La Raye” [=
Venus Estate] [converted from UTM, 13°55T4.7"N,
61°01T2.1"W], Choiseul: River Doree [converted
from UTM, 13°46'05.1"N, 61°01'54.6"W]. Soufriere:
Anse Chastanet [converted from UTM, 13°52'00.9"N,
61°04T0.3"W]. No Specific Quarter: no specific lo¬
cality (Dobson 1878; Allen 1908,1911; Miller 1913b).

Specimens captured/released (133).—Dauphin:
Monchy, 25 m [14°03'10.7"N, 60°56'03.2"W], 30.
Dennery: Dennery River, 0.25 km S, 2 km W Dennery,

II m [13°54'34.6"N, 60 o 54'16.2"W], 55; Au Leon Peak,
1 kmN, 1.75 kmE LaRessource, 319 m [13°57T4.4"N,
60°54'07.1"W], 7. Laborie: 1.25 km N, 0.75 km E
Saltibus, 398 m [13°48'59.8"N, 61°00'21.9"W], 3.
Micoud: Quilesse Forest Reserve, 2.5 km N, 8 km W
Micoud, 283 m [13°50'23.1"N, 60 o 58'25.8"W], 1; Trou¬
massee River, 1.3 km WMicoud, 40 m [13°49'13.9"N,
60°54'53.7"W] 37.

Acoustic records. —Clarke (2009) recorded this
species at seven of his 16 field sites: Anse La Raye:
Anse La Raye; Millet Forest. Castries: Union Trail.
Choiseul: River Doree. Dauphin: Sorciere River.
Soufriere: Anse Chastanet; Edmund Forest.

Commonly referred to as the “house bat,” this bat
was widely distributed on the Lesser Antillean islands
where historically several scientific names have been
used for its populations. Lindsey and Ammerman
(2016) included three of our specimens from St. Lucia
in their analysis of mitochondrial cytochrome-# gene
variation from throughout the geographic range of M.
molossus. They found that the St. Lucia specimens
clustered in a large polytomy including material from
Puerto Rico, Lesser Antilles, Guyana, Suriname, Bo¬
livia, and eastern Ecuador. Genetic divergence values

28

Special Publications, Museum of Texas Tech University

(1.2%) were low within this cluster. This was one of
three lineages recovered in their analysis, with the other
two consisting of individuals from western Ecuador and
from Brazil and Central America. The geographic area
of the samples clustered in the large polytomy included
the Lesser Antilles where Husson (1962) restricted the
type locality of M. molossus to Martinique. This led
us to agree with Dolan (1989) and Lindsey and Am-
merman (2016) in applying the name M. m. molossus
to this species on St. Lucia.

The results of an analysis of secondary sexual
variation in the length of forearm and seven cranial
measurements of eight male and seven female Molossus
are presented in Table 1. Males averaged larger in all
measurements, being significantly larger at the P < 0.01
level for greatest length of skull, zygomatic breadth,
and breadth across upper molars and at P < 0.05 level
for length of maxillary toothrow.

Our surveys underestimate the contribution of
Molossus to the local bat fauna because it flies higher
than our nets usually reach. Our samples were all
netted in open flyways or over water where the bats
were foraging and attempting to drink. This species
can be distinguished by its high, rapid flight in the
early evening when some birds were still active. This
commensal bat was often abundant over residential
areas and adjacent agricultural lands. Clarke (2009)
found five day roosts of this species and “All were in
abandoned or unoccupied buildings within wet forest.”
We observed these bats in the walls and ceilings of
buildings at all elevations (Fig. 13).

On the central east coast of the island, we placed
four mist nets across the Dennery River on the night
of 3 August 2008 with the hope of capturing Noctilio.
This shallow river was about 10 m wide with riffles
in some areas and small ponds in others. There was
a well-developed riparian forest on both sides of the
river, beyond that were buildings and small garden/
agricultural plots. The original flora of the area was
undoubtedly dry lowland scrub woodland but most of
this had been removed. We were unsuccessful in cap¬
turing Noctilio ; however, we caught four species, with
Molossus accounting for 71% of captures (70). Cer¬
tainly, these bats were using the river as a water source
as they exited from their day roosts, but it also served

Figure 13. Map of the geographic distribution of
Molossus molossus on the Lesser Antillean island of
St. Lucia. Symbols include: closed circles represent
specimens examined and open circles represent
literature records. The closed circle for the record of
Molossus molossus from Castries has been omitted
because its position has been taken by the star marking
the capital city.

as an open flyway in which emergent insects provided
a ready food source for these bats. The other three
species captured were M. plethodon (1), A.jamaicensis
x schwartzi (27), and T. brasiliensis (1), making this
fauna similar to the one from Monchy discussed next.

On the night of 13 March 2009, we netted 34
Molossus at Monchy, our northernmost collecting site
on St. Lucia. This was also the driest part of the island
where lowland scrub woodland probably prevailed
prior to colonization but building development and
agriculture had heavily impacted it. Five nets were
placed adjacent to the road into the village of Monchy,
over a small stream, and across a small access road.
This road lay between a small bog with semiaquatic
vegetation and a freshly ploughed field. Nearby, there
was a small plantation of bananas, a few mango trees,

Pedersen et al.—Bats of Saint Lucia

and a small chicken raising facility. Three other species
were netted at this location: two frugivores— B. caver -
narum (1) and A. jamaicensis x schwartzi (39)—and
one insectivore— T. brasiliensis (1).

The Diamond Botanical Garden was located a
short distance inland from the town of Soufriere, up
against the leeward slope of the Qualibou Depression.
This deep valley would presumably provide some
protection from tropical storms. Historically, the Dia¬
mond Estate raised limes, cocoa, and coconuts. The
botanical garden was established on this site in 1983
and contains many tropical flowering plants and other
ornamental plants that are flanked by several large trees
that were part of the original forest in the area. From
the Diamond Falls at the upper end of the garden, a
warm stream runs through the area, eventually draining
into the Soufriere River just below the gardens. We set
five nets in the garden and one across the stream. We
netted eight Molossus and three species of fruit-eating
bats— B. cavernarum (2), A. jamaicensis x schwartzi
(38), and S. paulsoni (1).

Our study site northeast of Saltibus (Fig. 14) was
along a steep ridge (398 m) north of the lowland areas
at the southwestern part of the island. The area was
dominated by a plantation of Caribbean pines, but tree
ferns and pepper plants were located in adjacent dis¬
turbed areas. Several inactive farm plots were located
below this site where we saw scattered mango and

Figure 14. Photograph looking to the south from our field
site north and east of Saltibus. The Caribbean Sea can be
seen in the far background. Four individuals of Molossus
molossus were captured at this site.

29

breadfruit trees. On the evening of 15 March 2009, we
netted in mist and light drizzle (23° C). We set five nets
in the plantation and across the access road in which
we captured four Molossus along with P. davyi (3), B.
cavernarum (2), M. plethodon (6), A. jamaicensis x
schwartzi (3), and S. paulsoni (2).

Between 14 and 17 March 2009, we netted 39
Molossus of which 27 were females and 12 males.
None of the females evinced gross reproductive activ¬
ity. Five of the males were scrotal, two having testes
lengths of 4, whereas seven males had testes in a non-
scrotal position with one having a testis length of 2. All
10 females taken 16-18 June 2007 were pregnant with
embryos that averaged 19.3 (10-24) in crown-rump
length. The single non-scrotal male taken during that
period had testes measuring 4 in length. Between 30
July and 4 August 2008, 90 Molossus were examined
for reproductive condition of which 71 were females
and 19 were males. The reproductive status of the
females was as follows: 55 were lactating; six were
lactating and each of which carried a single embryo
with a mean crown-rump length of 7.3 (5-10); six were
pregnant but were not lactating; and four revealed no
gross reproductive activity. Three of the males had
testes in an inguinal position. The remaining 16 males
were scrotal of which 15 had an average testes length
of 4.9 (2-6). A single male taken on 26 August 1967
had testes that measured 3.

Genoways et al. (2005) concluded that M.
molossus on Jamaica displayed aseasonal polyestry
with some individuals involved in reproductive activ¬
ity throughout most of the year. However, females
taken in mid-March in 2009, on St. Fucia revealed
no reproductive activity. This may be due to the fact
that February and March are the driest months of the
year. Genoways et al. (2001) did not take any pregnant
female M. molossus in March on Dominica, but by
April 1, three of 10 females were pregnant and three
other pregnant females were taken later that month. On
Barbados, four non-pregnant M. molossus were taken
in mid-April, coincident with the netting of juveniles,
indicating that parturition had occurred during the pre¬
vious months. As we view these data from the Antilles,
these bats appear to breed at various times during the
year but will become quiescent when local conditions
are not favorable.

30

Special Publications, Museum of Texas Tech University

Weights of 26 non-pregnant female bats taken
on St. Lucia between 14 and 17 March averaged 12.0
(11.0-13.0), whereas five scrotal males and seven with
testes in non-scrotal had mean weights, respectively, of
14.5 (13.1-17.1) and 13.9 (12.4-15.8). Between 16 and
18 June, 10 pregnant females had a mean body weight
of 15.4 (13.4-16.9), while a non-scrotal male from this
time weighed 14.7. Fourteen lactating taken

between 30 July and 4 August had a mean weight of
14.3 (12.3-15.1), whereas six females that were both
lactating and pregnant weighed an average of 15.6
(14.6-16.6). Fifteen scrotal males taken during this
latter period weighed an average of 17.1 (15.6-18.3).
On average, male Molossus weigh more than females,
although pregnant females do approach the weights
of males.

No gross abnormalities were observed in any
of these bats; however, one female exhibited a well-
defined white spot on the left ear (Dennery River, 3
August 2008).

Tadarida brasiliensis antillularum (Miller, 1902)
Brazilian Free-tailed Bat

Specimens examined (47).—Castries: Castries,
2 (KU 9663, 9666). Dauphin: Ruins of Marquis Es¬
tate, 1.6 kmN, 0.8 km E Boguis, 25 m [14°01'35.2"N,
60°54'40.6"W], 12 (TTU 110619-30); Monchy, 25
m [14°03'10.7"N, 60°56'03.2"W], 1 (TTU 113333).
Dennery: Dennery River, 0.25 km S, 2 km W Dennery,
11 m[13°54'34.6"N, 60°54T6.2"W], 1 (TTU 110631).
Gros Islet: Union Agriculture Station, 100 ft, 8 (KU
110248-55). Micoud: Troumassee River, 1.3 km W
Micoud, 40 m [13°49T3.9"N, 60°54'53.7"W], 1 (TTU
110632). Praslin: Fox Grove Inn, 1.1 km N, 0.2 km
W Mon Repos, 52 m [13 o 51'47.0"N, 60°54'22.8"W],
4 (TTU 110633-36). Soufriere: Edmund Forest Re¬
serve, 0.7 km N, 1.5 km E Fond St. Jacques, 550 m
[13°50'27.9"N, 60°59'47.6"W], 7 (TTU 110637—43).
No Specific Quarter: no specific locality, 11 (NMNH
110906-16).

Additional records. —Choiseul: River Doree
[converted from UTM, 13°46'05.1"N, 61 o 01'54.6"W]
(Clarke 2009). No Specific Quarter: no specific lo¬
cality (Miller 1902; Allen 1911; Shamel 1931; Jones
and Phillips 1970).

Specimens captured/released (135).—Dauphin:
Ruins of Marquis Estate, 1.6 km N, 0.8 km E Boguis,
25 m [14°01'35.2"N, 60°54'40.6"W], 135.

Acoustic records. —Clarke (2009) recorded this
species at two of his 16 field sites: Castries: Union
Trail. Dauphin: Marquis Estate ruins.

Based on holotype material from Roseau, Domi¬
nica, Tadarida brasiliensis in the Lesser Antilles were
thought to be smaller than those in the Greater Antil¬
les and subsequently named Nyctinomus antillularum
[=Tadarida brasiliensis antillularum ] by Miller (1902).
He assigned specimens from Montserrat, St. Kitts, St.
Lucia, and Tobago to this new taxon. In his revision of
the genus Tadarida , Shamel (1931) treated this species
under the name T. antillularum and added material from
Antigua, Guadeloupe, and Puerto Rico to this mono-
typic species. Schwartz (1955) reduced this species
to subspecific rank within the widespread mainland
species Tadarida brasiliensis. Although several closely
related subspecies of this free-tailed bat can be found
in the Antilles, T. b. antillularum is distributed from
Puerto Rico southward to St. Vincent (Schwartz 1955)
and is presently unknown from Barbados (Genoways
et al. 2011), Grenadines (Genoways et al. 2010), and
Grenada (Genoways et al. 1998). As indicated by Timm
and Genoways (2003), there are subtle morphological
variations among Antillean populations that separate
the subspecies T. b. antillularum and T. b. constanzae
(from Hispaniola).

Owen et al. (1990) raised the possibility that An¬
tillean populations of T. brasiliensis were more closely
related to T. b. cynocephala of the southeastern United
States than to T. b. mexicana of the southwestern United
States and Mexico. They studied these relationships
using morphometries and protein electrophoresis,
especially of the esterase-2 locus. They found that
T. b. cynocephala and T. b. mexicana could represent
separate species because of the larger cranial size of T.
b. cynocephala and different alleles for the easterase-2
locus. If their supposition is correct, it would represent
a unique invasion of the West Indies from the north
(Rodriguez-Duran and Kunz 2001). There is great need
for a modern molecular phylogenetic analysis of the
entire Tadarida brasiliensis complex including those
in the Caribbean basin.

Pedersen et al.—Bats of Saint Lucia

31

Our analyses for secondary sexual variation of
the length of forearm and seven cranial measurements
of 10 male and 15 female Tadarida (Table 1) revealed
that only the greatest length of skull in males was sig¬
nificantly larger (P < 0.01). In addition, males averaged
larger in condylobasal length, whereas females aver¬
aged larger in three measurements—length of forearm,
postorbital constriction, and mastoid breadth.

The Fox Grove Inn was a small resort above the
Mamiku River on the Atlantic Coast of St. Lucia where
we made our headquarters during our three surveys
(Fig. 15). This area was a sugar plantation during the
colonial period, but now produces a variety of fruits,
including bananas. On the night of 29 July 2008, we
placed four mist nets among the ornamental plantings,
between buildings, and one across the 10 m by 30 m

Figure 15. Map of the geographic distribution of
Tadarida brasiliensis on the Lesser Antillean island of
St. Lucia. Symbols include: closed circles represent
specimens examined and the open circle represents a
literature record. The closed circle for the record of
Tadarida brasiliensis from Castries has been omitted
because its position has been taken by the star marking
the capital city.

resort swimming pool. Over the course of the evening,
we captured four of these free-tailed bats in this net lo¬
cated about 0.5 m above the surface of the water. These
bats arrived after 1800 hr and probably were coming
to the pool to drink. Other nets at this site captured M.
plethodon (1) and A. jamaicensis x schwartzi (18).

In the late afternoon and evening of 17 June 2007,
we collected bats in and around the ruins of Marquis
Estate in the Quarter of Dauphin. This area was domi¬
nated by abandoned agricultural lands that bordered the
Marquis River. Four nets were set to take advantage of
mango trees, bananas, scrub-forest edge, and fly ways.
Three large nets (18 m and two 12 m) were stretched
across the Marquis River in the hopes of catching
Noctilio. One of the ruined estate buildings housed a
breeding colony of more than 1,000 of these free-tailed
bats. We netted 147 individuals from this colony, with
92 being females and 55 males. Eighty-seven of these
females were pregnant, carrying a single embryo of
which six averaged 15.0 (14-18) in crown-rump length.
Six scrotal males had testes with a mean length of 2.5
(2-3). Three females were netted between 31 July
and 4 August 2008, two of which were lactating and
the third was pregnant and lactating, with the embryo
measuring 22 in crown-rump length. The 10 males
collected between 30 July and 2 August 2008 were
all judged to have testes in an inguinal position, with
seven having a mean testes length of 2.3 (2-3). On 26
August 1967, seven female Tadarida were obtained on
St. Lucia of which six were lactating and one exhibited
no gross reproductive activity. Mainland populations
of this species are monoestrous producing a single
young in May-June and fledging them generally by
early August (LaVal 1973; Wilkins 1989). Although
this island population may be following a similar pat¬
tern, parturition and lactation extend through August.
Either the island’s population reproductive cycle was
not as highly synchronous as it was on mainland or there
was a postpartum estrus leading to a second period of
reproduction.

Six pregnant free-tailed bats captured in mid-June
had a mean weight of 9.6 (9.0-10.0), whereas seven
adult males from this time had a mean weight of 7.7
(6.9-8.3). A pregnant and lactating female taken on
30 July weighed 11.7, whereas two lactating females
taken between 31 July and 4 August weighed much

32

Special Publications, Museum of Texas Tech University

less at 9.5 and 9.4, respectively. Nine males netted in 9.8 (8.5-11.4), which was more than 2 grams heavier

late July and early August had an average weight of than the males in June.

Discussion

Achieving a better understanding of the ecologi¬
cal and evolutionary mechanisms responsible for pat¬
terns of faunal distribution along island archipelagos is
a long-standing goal of biogeographical research (Pati¬
no et al. 2017). Dispersal of species along island chains
is influenced strongly by distances between islands
(Koopman 1976; Genoways 1998; Whittaker 1998),
regional storm patterns, and species vagility (Paine
1977; Waters 2011; Steinbauer et al. 2016; Steinbauer
2017). But a persistent and mostly unresolved question
in island biogeography is the extent to which insular
patterns of animal movement and distribution are due
to either stochastic (storm transport—Connor and
Simberloff 1978,1979; Simberloff 1978,1980; Connor
and McCoy 1979; Brown 1986; Fleming and Murray
2009; Genoways et al. 2010) or deterministic factors
(that is, dispersal behavior—Lawlor 1986; Lomolino
1986; Patterson and Atmar 1986). Despite the wealth
of survey data, voluntary movement patterns of bats
throughout the Lesser Antilles are effectively unknown
and would be certainly species-specific (Carstens et al.
2004; P. Larsen et al. 2010; R. Larsen et al. 2012,2017).
If stochastic rather than deterministic mechanisms drive
the movement of bats among islands, the distributional
data should be relatively consistent among species. For
St. Lucia, this is clearly not the case.

The known fauna of St. Lucia consists of only
nine species: one noctilionid (A. leporinus), one mor-
moopid (P. davyi), five phyllostomids (M plethodon,A.
jamaicensis x schwartzi, B. cavernarum , A. nichollsi ,
and S. paulsoni), and two molossids (M molossus
and T. brasiliensis). This fauna is smaller than those
reported for the other islands in the Lesser Antillean
Faunal Core—Montserrat, 10 species; Guadeloupe,
12; Dominica, 12; Martinique, 11; and St. Vincent, 12
(Table 2).

To gain a broader understanding of the role of
natural dispersal in the development of the Lesser
Antillean bat faunas, we have constructed a tentative
framework for such events. Using this, we have ana¬
lyzed the structure of the St. Lucian bat fauna to learn

if there is a reason unique to St. Lucia for its reduced
fauna. We are well aware that additional survey work
on the island could overturn this view; however, we
believe that this framework and analysis should be
useful in understanding the formation of the bat faunas
along the Lesser Antillean archipelago.

Framework for Natural Dispersal

Scientists studying human-mediated invasion
biology of plants and animals have worked to develop
a framework for how this process would proceed
(Williamson and Fitter 1996; Richardson et al. 2000;
Britton-Simmons and Abbott 2008; Valery et al. 2008;
Blackburn et al. 2011). Because these efforts were
centered on human-induced invasions, their framework
is not directly applicable to natural dispersal events, but
some of the elements are similar and can be used as
guideposts to develop a framework for natural disper¬
sal. Invasions are discussed in terms of barriers to be
overcome and the stages or events that allow the spe¬
cies to succeed or fail to move forward with dispersal
(Blackburn et al. 2011). In our discussion, we use the
term propagule as used by Simberloff (2009; see also
Lockwood et al. 2005, 2009) meaning: “a group of
individuals arriving in a place.” Because the natural
dispersal events of interest to our research involve over¬
water dispersal by volant species, we will develop the
framework around these events as they may occur in
relation to the islands of the Caribbean.

Philopatry. —In our theoretical natural dispersal
scenario, the first barrier to be overcome would be
philopatry. This is the tendency of bats as well as other
organisms to remain close to their place of birth. This
is simply because they are familiar with the local fruit¬
ripening sequence, where concentrations of insects may
occur, where appropriate roost sites are to be found, and
the presence or location of conspecifics. Resources
beyond this area are unknown and therefore pose a
risk. Therefore, displacement and/or dispersal of these
animals requires either internal (sex-specific dispersal,
conspecific competition, etc.) or external factors that

Pedersen et al.—Bats of Saint Lucia

33

Table 2. Species distribution matrix for the bats of Lesser Antilles. Refer to key below the table for
more information.

Lesser Antillees Faunal Core

All documented species

8

9

5

7

6

8

9

10

11

10

12

8

4

15

12

11

9

12

6

4

3

3

2

4

5

12

Extant species

6

8

5

7

6

8

9

7

8

10

12

8

4

8

12

11

9

12

6

4

3

3

2

4

5

12

Non-endemic species

3

4

3

3

3

4

4

4

4

4

4

4

3

4

6

5

5

6

3

3

2

2

2

3

4

10

Lesser Antillean endemics

3

4

2

4

3

4

5

3

4

6

8

4

1

4

6

6

4

6

3

1

1

1

0

1

1

2

% Endemics

50

50

40

57

50

50

56

43

50

60

66

50

25

50

50

55

44

50

50

25

33

33

0

25

20

17

Carnivore ___

| NoctiUo leporinus \ • m m X m m • m »•»»»• | • •

Large phytovore

Brachyphylla cavernarum

•

•

•

•

•

X

•

•

•

X

X

•

•

•

•

•

•

•

•

Artibeus jamaicensis

Chiroderma improvisum

• N • •

Artibeus schwartzi

H •

• • • • •

Artibeus lituratus

•

• • • •

Artibeus planirostris

•

Small phytovore

Ardops nichollsi

• •••• •••• X • • • •

Sturnira angeli

• • • •

Sturnira paulsoni

• •

•

Dermanura sp.

•

Nectarivore

Monophyllus plethodon

Glossophaga longirostris

Anoura geoffroyi

•

•

Insectivore

Molossus molossus

Tadarida brasiliensis

Natalus stramineus

• •

•

• • x • • •

X

• •

Eptesicus guadeloupensis

•

Myotis dominicensis

•

•

Pteronotus davyi

•

• • •

•

Eptesicus sp.

•

Myotis martiniquensis

•

Pteronotus fuscus

•

Micronycteris buriri

•

Myotis nyctor

•

•

Micronycteris megalotis

•

Peropteryx trinitatus

•

Fossil record only

Mormoops blainvillei

t

t

t

t

Macrotus waterhousii

f t

t

Mormoops megalophylla

t

t

Phyllonycteris cf. major

t

t

Pteronotus (portoricensis)

t

f

Pteronotus quadridens/macleayi

t

Natalus cf. major

t

Data: Pedersen et al. 2013, Stoetzel et al. 2016, Pedersen et al. 2018

Blue text - Island surveyed by authors 1993-2011

Blue # - Effort added at least one species to this category

Red - Lesser Antillean endemic species

Within guild, taxa are arranged by distribution, north > south

The vertical line between Barbados and Bequia represents Koopman's Line.

H - A. jamaicensis x schwartzi hybrid (see text)
Dot - Indicates published record
N - Unpublished record
X - Both extant & fossil records
f - Fossil only

Empty box - species that is 'missing' on SLU

34

Special Publications, Museum of Texas Tech University

disrupt the environment or destroy resources—both
referred to as “upheavals” by Waters (2011). Common
upheavals in the Caribbean would be hurricanes, tropi¬
cal storms, flooding, droughts, landslides, earthquakes,
volcanic eruptions and their associated pyroclastic
flows, changing sea levels, and habitat destruction as¬
sociated with human occupation (Pedersen et al. 2012).

Dispersal mechanisms. —Once oceanic island
bats have been motivated/forced to leave their home
island or the mainland, the next barrier to surmount
would be the overwater distance between islands. In a
study of long-distance dispersal to oceanic islands in the
Pacific, Gillespie et al. (2012) described the forces that
move organisms as “vectors”—“Key elements contrib¬
uting to the effectiveness of these vectors as dispersal
agents are their sustained velocity and directionality,
together with their capacity to pick up and transport
propagules” (Simberloff 2009; see also Lockwood et
al. 2005, 2009). The most relevant of these vectors to
our discussion is the dispersal of bats among islands
that is facilitated by prevailing winds or tropical storms.
Contemporary storms in the Caribbean follow a general
pattern—forming over the Atlantic Ocean, the storms
move from east to west; at some point the storm’s track
will make a turn to the north or northwest; finally, as
the storms weaken they will turn to the right (east); if
the storms hold together they eventually disintegrate
over the North Atlantic. The paleoclimatological data
demonstrates that there are several variations on this
generalized track, but all favor the general movement
of bats from northeastern South America up through
the Lesser Antillean chain.

Although the trade winds are of lower velocity
than the major storms, Gillespie et al. (2012) believed
they could be effective in moving a propagule over
short distances. At the present time, the trade winds
blow steadily (18 to 20 km/hr) through the Lesser Antil¬
les toward the equator, from the northeast. These winds
may assist the southward dispersal among some islands
by such species as A. jamaicensis, N. stramineus , and
T. brasiliensis. In particular, the available genetic data
from A. jamaicensis supports this dispersal pattern and
indicates a recent (less than 15,000 years ago) south¬
ward expansion by this species throughout the Lesser
Antilles (P. Larsen et al. 2010). Clearly, some species
of bats are stronger fliers than others. Given what we

know about foraging distances on individual islands
(Pedersen et al. 2006, unpublished data collected on
Montserrat), the distances between many islands could
be crossed in a normal evening’s flight by several spe¬
cies, e.g., N. leporinus, B. cavernarum, A. jamaicensis,
A. schwartzi, M. molossus, and T. brasiliensis. This is
particularly true in the northern Lesser Antilles where
the distances between islands would have been even
less during the Last Glacial Maximum.

Arrival and Survival. —The next barrier for dis¬
persing bats to overcome would be survival in their new
surroundings (Blackburn et al. 2011). Translocated
bats may arrive in poor health and it is critical that
they find food and shelter almost immediately. Some
species apparently have the capability of resting on
small, inhospitable islands for a few days before seek¬
ing better habitat on other islands. This is what we
believe occurred (Genoways et al. 2010) following
extensive damage from Hurricane Ivan to the forests
on Grenada, resulting in a small group of A. lituratus
appearing on the island of Mayreau for about a week
before disappearing.

Translocated bats would also come into con¬
tact and competition with the incumbent species for
resources. This competition could be formidable if
this island’s habitats and resources had been severely
damaged by the same storm that displaced the bats from
their previous home. For many species of bats, this ini¬
tial survival may be the most critical stage of dispersal
(Gannon and Willig 1994; Pedersen et al. 1996, 2010,
2013; Jones et al. 2001; Presley et al. 2008; Willig et al.
2010). Jeschke and Strayer (2005), studying human-
mediated dispersal of vertebrates, found that the lowest
success rate occurred in this initial step, rather than in
any of the later stages. Their results showed successful
introduction rates of 2.0 to 6.3% for terrestrial mam¬
mals, but without the aid of humans, the introduction
rate for natural dispersal would be expected to be less
than this.

Colonization. —The next barrier facing displaced
bats would be adaptation to their new habitat. Islands
with higher elevations have a wider range of habitats
and are therefore more likely to provide a match to
the propagule’s native habitat (Steinbauer 2017),
that is, “Successful colonization and establishment

Pedersen et al.—Bats of Saint Lucia

35

are more likely in environments that approximately
match the source environment” (Gillespie et al. 2012).
Vermeji (1996; see also Colautti et al. 2006) opined
that “weedy” or opportunistic species would be better
dispersers because of their broader habitat tolerance,
which would be particularly true in the disturbance
prone Lesser Antillean islands— A. jamaicensis and
M. molossus being the bat exemplars of this. For more
specialized species of bat, they will need to identify
year-around food supplies, day roosts, and night roosts
large enough to serve as maternity/bachelor colonies
if necessary, and a sustaining range of microclimates.
It is possible that adaptation to these factors happens
quickly, as discussed in some detail elsewhere (Lucek
et al. 2012; Kwiecinski et al. 2018).

One factor in survival and successful coloniza¬
tion may be the sequence in which species arrive on an
island because “only those species differing sufficiently
from species already present are likely to become
established” (Vermeji 1996). This phenomenon was
termed the “priority effect” by Steinbauer (2017) and
the “progression rule” by Waters (2011). This “priority
effect” can be offset by propagule pressure—the num¬
ber of individuals arriving (Williamson and Fitter 1996;
Blackburn et al. 2011). Simberloff (2009) showed
that as the propagule size increases, the likelihood of
establishment increased and the number of times that
propagules arrive diminishes impacts of environmental
stochasticity. In the long term, a failure of a species to
survive and ultimately colonize an island, in the first
instance of dispersal, does not predict what will happen
in subsequent events.

Reproduction. —The final barrier to the successful
dispersal of bats to islands would be sustained repro¬
duction. The idea of the lone pregnant female being
a successful propagule must be abandoned in favor of
identifying what is the minimum viable propagule for
each species of bat in the system. Bats have low repro¬
ductive rates. On St. Lucia, P. davyi, B. cavernarum,
and T. brasiliensis produce a single young per year
and the other species may produce two young per year.
Beyond replacing the original propagule, the process
of generating a sustainable population can take several
years with these low reproductive rates.

Lockwood et al. (2005) believed that low levels
of genetic variation in small propagules will decrease

the probability of non-native population establishment.
Certainly, the depression of genetic variability in the
original propagule can negatively impact reproductive
success as inbreeding progresses. However, Presley
and Willig (2010) argued that many species of bats in
this archipelago exist as a metacommunity, inferring
that dispersal amongst islands may not be as much of
an obstacle as discussed herein. Indeed, the highly
vagile molossid, T. brasiliensis , exhibits a consider¬
able amount of community structure throughout the
Bahamas (Speer et al. 2017). This suggests that body
size and vagility are poor predictors of connectivity in
this system. Such connectivity would overcome the
potential reduced genetic variability in a propagule, via
the steady exchange of new genetic material between
fragmented patches which could promote long-term
species survival (Trakhtenbrot et al. 2005).

Hypotheses regarding population-level genetic
variation can easily be tested, however nearly all ge¬
netic data that have been generated from the bats of the
Lesser Antilles has been from particular mitochondrial
genes (e.g., cytochrome-#). Although the nucleotide
variation observed in these datasets is appropriate for
resolving species or subspecies-level taxonomy, it is not
necessarily appropriate for resolving population-level
questions of genetic variation. Therefore, we recom¬
mend additional studies that utilize appropriate genetic
approaches with the resolving power for testing hy¬
potheses regarding population-level genetic variation.

If dispersing species of bats fail to accomplish any
of the stages in our proposed framework, the species
will be locally extirpated. Jones et al. (2003) studying
the causes of extinctions in bats found that the great¬
est risk factor was associated with small geographic
ranges. Other risk factors included island endemicity,
low birth rates, and low wing aspect ratios. These fac¬
tors clearly indicate that it is island populations of bats
that are most at risk of extinction, relative to mainland
species of bats. There is an adequate fossil record for
bats in the Greater Antilles and a developing record for
the Lesser Antilles, but these come from the northern
Limestone Caribbees (Pregill et al. 1994; Orihuela and
Tejedor 2015; Boudadi-Maligne et al. 2016; Stoetzel
et al. 2016) and little or no fossil record is available
for bats in the southern Lesser Antilles including St.
Lucia. Without a fossil record, we cannot determine
which species have failed in natural dispersal events

36

Special Publications, Museum of Texas Tech University

on the islands, but our data on the modern fauna will
allow an assessment of the St. Lucia fauna and its place
in the Lesser Antilles.

The “Missing” Species of Bats of St. Lucia

The known bat fauna of St. Lucia consists of
nine species but there are a number of species that are
noticeably absent—a) Pteronotus fuscus, Micronyc-
teris buriri, Glossophaga longirostris, and Artibeus
lituratus , each known from the adjacent island of St.
Vincent to the south; b) Myotis martiniquensis and
Natalus stramineus, which are found immediately to
the north on Martinique; and c) Myotis nyctor to the
east on Barbados (Table 2). These seven “missing”
species represent six disparate taxonomic groups:
Natalidae, Vespertilionidae, Mormoopidae, and three
phyllostomatid subfamilies—Glossophaginae, Phyl-
lostominae, and Stenodermatinae. With the exception
of A. lituratus , these are small, cave or cavity roosting,
presumably monoestrous bats (except Glossophaga ),
which feed primarily on insects, or will do so season¬
ally (that is, Glossophaga ).

Natalus stramineus: N. stramineus is a Lesser
Antillean endemic species known from most islands
between Anguilla and Martinique but is absent from
islands to the south of Martinique. This is in keeping
with Genoways et al. (2005), who hypothesized that
natalids originated and radiated in the Antilles, with N.
stramineus appearing in the Lesser Antilles. Despite
being small-bodied and seemingly delicate bats, the
natalids evolved in disturbance prone environments
and N. stramineus is found scattered throughout the
northern Lesser Antilles, often in rather large numbers
(Pedersen et al. 2007). This bat has specific roost
requirements (Tejedor 2006) and the lack of suitable
roost sites (moist, dark caves) may be partly responsible
for the lack of successful colonization of St. Lucia by
this species.

Myotis martiniquensis : Large numbers of this
single-island endemic have been netted on Martinique
(192 of 1859 total bat captures in foraging and com¬
muting habitat, 10.3%) (Catzeflis et al., personal com¬
munication), suggesting that extant propagule pressure
is not the reason for the lack of movement southward
to St. Lucia (Lockwood et al. 2005). Its wide-ranging

choice of roosts—caves, rock crevices, tree cavities,
and human structures—would improve its chances of
surviving in the aftermath of tropical storms or would
increase its chances of successful colonization of a
new island through storm transport. R. Larsen et al.
(2012) presented data indicating that members of the
genus Myotis invaded the Lesser Antilles at least twice.
The ancestor of M. dominicensis and M. martiniquen¬
sis entering the islands in the Pliocene, 4 to 5 million
years ago. It is unknown whether or not members of
this genus ever successfully colonized St. Lucia or if
additional fieldwork will identify Myotis on the island.

Myotis nyctor. This species is only known from
Barbados and Grenada, presumably colonizing the Ca¬
ribbean from South America, this being based on close
genetic and morphological affinities (R. Larsen et al.
2012). On Barbados, this species was common in the
protective rocky limestone walls of numerous gullies
and caves. Elsewhere, appropriate roost sites could be
a limiting factor for this relatively delicate forest bat.
R. Larsen et al. (2012) presented data to indicate that
M. nyctor represented a second invasion of the Lesser
Antilles and probably populated the islands during
the Pleistocene and reached Barbados sometime after
700,000 years ago. It is unknown whether or not M.
nyctor has gone locally extinct on St. Vincent or St.
Lucia or if this species ever colonized these islands.
Additional fieldwork may or may not identify additional
populations of Myotis in the southern Lesser Antilles.

Pteronotus fuscus : This is a large, insectivorous
bat, easily capable of moving between St. Vincent and
St. Lucia. Indeed, it was caught on the northern tip of
St. Vincent a mere 42 km away. The nearest popula¬
tion of P. fuscus to St. Vincent is on Trinidad and the
northern coast of South America indicating that they
are capable of covering long distances. This is a cave
roosting species, so roost site availability could also
be a limiting factor to its colonization of St. Lucia.
Pavan and Marroig (2016) placed the divergence of P.
davyi and P. fulvus at about 1.6 million years ago and
the divergence among P. mesoamericanus, P. mexica-
nus, and P. fuscus at about 1.3 million years ago. This
could have given P. davyi priority in dispersing into the
Lesser Antilles. However, the distribution of P. davyi
extends from Marie Galante southward to Dominica,
Martinique, St. Lucia, and Grenada, but it is absent from

Pedersen et al.—Bats of Saint Lucia

St. Vincent the only island where P. fuscus occurs. This
certainly could be an example of the priority effect, with
the exclusion based on overlap in prey items or even
more probable competition for very limited roost sites
on both islands. An anecdotal piece of information
indicating a shortage of cave roost sites on St. Lucia
was the discovery by Arendt and Anthony (1986) of a
large colony of B. cavernarum in a cavity in acomat
boucan tree. This is a highly unusual day roost site for
this cavernicolous species.

Micronycteris buriri : This is relatively rare
single-island endemic found on the adjacent island
of St. Vincent where it represented only 1% of all
captures (19/1965). This cave bat is closely related to
the congeneric, M. megalotis , which is equally rare on
Grenada (Genoways et al. 1998). As with many other
“missing” taxa, the availability of appropriate roost
sites may have limited its successful colonization of
St. Lucia. Alternatively, given the hypotheses put forth
by P. Larsen et al. 2011, it is possible that M. buriri is
the result of intense and rapid local adaptation to St.
Vincent and has simply not yet successfully colonized
St. Lucia to the north.

Glossophaga longirostris : This is a common spe¬
cies of bat on the adjacent island of St. Vincent. This
facultative insectivore accounted for 18% of all cap¬
tures on St. Vincent (356/1965)—given this relatively
large population, its absence on St. Lucia is the most
puzzling of all species. It is possible that its absence
is due to competition with the incumbent pollinator
on St. Lucia— Monophyllus (Waters 2011; Steinbauer

2017) —perhaps a demonstration of the priority effect
or progression rule. It should be noted that significant
populations of several species of Glossophaga are
available for dispersal from source areas in northern
South America and Central America. Two species of
Glossophaga entered the Antilles from opposite ends—
G. soricina from the west to Jamaica (Genoways et
al. 2005) and G. longirostris from the south up to St.
Vincent. Only on the islands of Jamaica and St. Vincent
do the genera Monophyllus and Glossophaga co-occur.

Artibeus lituratus : This species was rare on St.
Vincent with only two specimens taken among the 1965
bats captured during our work there (Kwiecinski et al.

2018) . However, these were netted at the northern tip of

37

that island from which St. Lucia was easily seen across
the channel. A. lituratus is primarily a tree-roosting
species and has often been netted in groves of coconut
trees, which are common on the north end of St. Vincent
and the adjacent southern shore of St. Lucia. The ab¬
sence of A. lituratus possibly could be another example
of the priority effect with/I schwartzi as its competitor.
We believe that A. schwartzi is a product of reticulate
evolution on St. Vincent (P. Larsen et al. 2010) and it
approaches the size of A. lituratus (Jones 1978) and
they may compete, especially for food resources. The
priority effect could account for the low numbers of A.
lituratus on St. Vincent and its absence from St. Lucia.
Alternatively, the genetic data presented by P. Larsen et
al. (2013) indicate a very recent expansion event by A.
lituratus throughout the Neotropics, and therefore this
species may simply not had enough time to establish
populations in the southern Lesser Antilles.

The Distribution of Bats Throughout the Lesser
Antilles

The Lesser Antillean Faunal Core. —The “Lesser
Antillean Faunal Core” refers to the extant bat fauna of
the central Lesser Antillean islands—Montserrat to St.
Vincent. This fauna is characterized by the presence
of ten or more species that includes several endemic
taxa. The southern zoogeographic limit of the Lesser
Antillean bat fauna is demarcated as Koopman’s Line
(Genoways et al. 1998, 2010; Kwiecinski et al. 2018)
and is located just south of St. Vincent. On islands
south of this line, the bat faunas are composed of South
American and widespread species of bats. A similar
line for avifauna exists between Tobago and Grenada
designated as Bond’s Line (Lack 1976; Wunderle 1985;
but see Ricklefs and Bermingham 2004). This Lesser
Antillean bat fauna has two primary sources of coloni¬
zation—Central America-Greater Antilles and northern
South America. Different assemblages of bats from
opposite ends of the archipelago should systematically
colonize islands. The subsequent boundaries and zones
of overlap will vary with the individual species of bat.
But without a broad fossil record, we cannot determine
the nature of this overlap historically, nor understand
why some species failed to disperse more broadly.
However, the assemblage of fossil bats on the island
of Marie Galante would suggest that these boundaries
shift and are influenced by climatic conditions. During

38

Special Publications, Museum of Texas Tech University

glacial periods, this assemblage contained several spe¬
cies that are considered to have been derived from the
north (Greater Antilles), this alternating with species
moving up the chain from the south during interglacial
events (Stoetzel et al. 2016).

Plant-visiting bats of South American origin
are found on St. Vincent and islands to the south (A.
lituratus, A. schwartzi, and G. longirostris), albeit S.
paulsoni is found on St. Lucia. Those endemic species
with origins in the Greater Antilles occur on St. Vincent
and islands to the north ( B. cavernarum , A. nichollsi,
and M. plethodon). The situation with Artibeus is far
more complicated and involves reticulated evolution
among multiple species of Artibeus converging on St.
Lucia and St. Vincent from both northern and southern
invasion routes (P. Larsen et al. 2010).

Such feeding guild assignation is also compli¬
cated by the fact that several plant-visiting bats are
facultative and/or seasonal insectivores: A.jamaicensis
(Herrera et al. 2001,2002; Orr et al. 2016), B. caverna¬
rum (Pedersen et al. 1996; Lenoble et al. 2014a), and
the two glossophagines, Monophyllus and Glossophaga
(Clare et al. 2014). This dietary plasticity is most
commonly noted in reproductive females who have an
increased demand for nutrients and may also reflect the
seasonal availability of preferred forage (Patterson et
al. 2003). By itself, such omnivory is not obviously
related to species dispersal per se, but it has a strong
effect on apparent guild composition and may impact
the propagule sequence (Meyer et al. 2015). Certainly,
omnivory is an effective adaptation in terms of survival
in the aftermath of natural disasters, such as volcanic
eruptions and hurricanes (Pedersen et al. 1996, 2012).

There are three species of dedicated insectivo¬
rous bats on St. Lucia. To the north, Martinique has
five, and St. Vincent to the south has four species of
insectivores (Table 2). The apparently depauperate
insectivore fauna of St. Lucia poses several questions,
including: a) is there something about the physiography
or habitat diversity of St. Lucia that could affect its
fauna and interfere with species richness in the insec¬
tivore guild (Table 3); b) is the propagule pressure too
low—is St. Lucia simply located “too far” south for N.
stramineus and M. martiniquensis, and “too far” north
for M. buriri , P. fuscus, and perhaps even M. nyctor, to

colonize (Table 2)? If this is the case, St. Lucia may
also be an island “too far” north for the phyllostomids,
G. longirostris and A. lituratus.

Regardless, the bat fauna of St. Lucia is depau¬
perate relative to the neighboring islands. Its species
inventory could change with the next expedition to the
island, as we have seen with some of our earlier work
(Lindsay et al. 2010; Beck et al. 2016). Nevertheless,
it can be informative to examine potential reasons as to
why only nine species have been taken on the island un¬
der conditions and field efforts that have yielded larger
numbers of species on other Lesser Antillean islands.

Survey bias , netting effort , and roost surveys .—
Accurate species inventories for an island are ham¬
pered by the inadequacy of ground-based mist netting
strategies, something that has been painfully obvious
to field biologists who study species-specific responses
to mist nets and species-specific ability to avoid mist
nets (Francis 1989; Simmons and Voss 1998; Barber et
al. 2003; Berry et al. 2004; Lang et al. 2004; R. Larsen
et al. 2007; Meyer et al. 2011). This phenomenon
was clearly demonstrated by R. Larsen et al. (2007)
who found that on average, only 3.2% of bats passing
through a flyway are captured in a mist net.

Caves, rock fissures/over-hangs, and their man¬
made equivalents (mines, wells, cisterns, abandoned
buildings) provide critical refiigia for bats during the
breeding season and in times of natural disturbance
(Gannon and Willig 1994; Pedersen et al. 1996;
Rodriguez-Duran 2010). The availability of roosts
is thought to be the most critical limiting factor in
the successful colonization of islands by bats in the
region (Pedersen et al. 2003, 2005, 2006; Genoways
et al. 2007a, 2007b, 2007c). The loss of even a single
cave roost on a small island, via earthquakes, volcanic
activity, or human action can have a disproportional
impact on an island’s fauna (Pedersen et al. 1996,2012;
Genoways et al. 2007b; Cooke et al. 2017). Davalos
and Russell (2012) attributed the Holocene extinction of
bats in the Caribbean to rising sea levels and the flood¬
ing of low lying caves. Soto-Centeno and Steadman
(2015) disputed this interpretation of the fossil record,
yet these data underline the importance of caves and
other shelters to bat populations in this region. Un¬
like our inventory work on other islands in the region

Pedersen et al.—Bats of Saint Lucia

39

Table 3. Guild composition and survey efforts. Capture data include only sites located away from known roosts.
Data from Catzeflis et al., pers. comm. (Martinique), Kwiecinski et al. 2018 (St. Vincent), and this study (1967,1987,
2007-2009; St. Lucia). Species classified as follows: Carnivore —Noctilio leporinus ; Large fruit bats —Artibeus
jamaicensis, A. lituratus, A. schwartzi, Brachyphylla cavernarum. Other fruit bats —Ardops nichollsi , Sturnira angeli,
S. paulsoni; Nectarivores —Glossophaga longirostris, Monophyllusplethodon; and Insectivores —Micronycteris buriri ,
Myotis martiniquensis, Pteronotus davyi, P. fuscus, Natalus stramineus, Tadarida brasiliensis, and Molossus molossus.

Martinique

St. Fucia

St. Vincent

Guild composition

Extant species

11

9

12

Lesser Antillean endemics (%)

6(55)

4(44)

6(50)

Carnivore taxa (%)

1(9)

1(11)

1(8)

All fruit bats (%)

4(36)

4(44)

5(42)

Large fruit bats (%)

2(18)

2(22)

3(25)

Other fruit bats (%)

2(18)

2(22)

2(17)

Nectarivore taxa (%)

1(9)

1(H)

2(17)

Insectivore taxa (%)

5(45)

3(33)

4(33)

Taxa relative to island elevation and area

Elevation (m)

1,397

950

1,234

Island area (sq km)

1,060

617

345

All taxa / elevation (x 1,000)

7.9

9.5

9.7

All taxa / area (x 1,000)

10.4

14.6

34.8

Fruit bat species / elevation (x 1,000)

2.9

4.2

3.2

Fruit bat species / area (x 1,000)

3.8

6.5

11.6

Nectarivore species / elevation (x 1,000)

0.7

1.1

0.8

Nectarivore species / area (x 1,000)

0.9

1.6

2.9

Insectivore species / elevation (x 1,000)

3.6

3.2

2.4

Insectivore species / area (x 1,000)

4.7

4.9

8.7

Sampling effort

Locations

24

20

28

Number of nets

na

119

172

Netting locations west:east

13:11

10:10

14:14

Netting locations above:below 250m

12:12

10:10

14:14

Natural roosts visited

na

2

8

Capture data (% of captures)

All species

1,859

1,520

1,679

Fruit bats (%)

1,244 (67)

1,125 (74)

1,010(60)

Artibeus only (%)

612(33)

998 (66)

766 (45)

Nectarivores (%)

259(14)

160(11)

480 (23)

Insectivores (%)

356(19)

229 (15)

233(14)

Capture rates—Bats per net-night

Fruit bats

na

9.4

5.8

Artibeus only

na

8.4

4.4

Nectarivores

na

1.3

2.8

Insectivores

na

1.9

1.3

Island average

na

12.2

10.2

40

Special Publications, Museum of Texas Tech University

(Pedersen et al. 2013), our cave surveys did not increase
the number of species found on either St. Lucia or St.
Vincent. Future efforts on St. Lucia must focus on
locating roosts and their potential denizens, such as N.
stramineus, P. fuscus, M. buriri, G. longirostris , and at
least one species of Myotis.

Paleoclimatology and storm transport. —The
present-day climate in the Lesser Antilles is dictated in
part by the seasonal displacement of the inter-tropical
convergence zone (ITCZ), which moves north of the
Equator in summer and then south of the Equator in
winter (Royer et al. 2017). At a much greater time
scale, the paleoclimatological data indicate that the
mean position of the ITCZ moves significantly to the
north during interglacial periods and then south dur¬
ing glacial periods (Schmidt and Spero 2011). It has
done this at least twice during the last 11,000 years
(Hodell et al. 1991; Fritz et al. 2011; Malaize et al.
2011). When the ITCZ is located to the south, storms
penetrate the Caribbean directly from the east. When
the ITCZ swings to the north, it pushes hurricane tracks
and generally drier conditions along the Lesser Antil¬
les towards the Bahamas (Royer et al. 2017). Such
shifts typically leave the southern Lesser Antilles with
a moist, relatively storm-free period that may affect
occupation and colonization of those islands by bats.

Along a storm’s path, the worst damage is
typically associated with the right-front quadrant of
the storm. Empirical data indicates that the primary
debris field (such as bats and birds) is most likely to
be spread across a zone 10° to 35° to the left of the
storm path (Snow et al. 1995). When the ITCZ moves
southwards, bats are likely to be ejected from the storm
over open-ocean without a chance of landfall. When the
ITCZ moves to the north, storms skirt to the east along
the archipelago, shedding a debris field over islands to
the NW-NNW of the storm track. Storm transport of
bats from the south to St. Lucia is therefore more likely
than bats being “blown” to St. Lucia from the north,
regardless of time scale. However, the Atlantic trade
winds blow steadily (18-20 km/hr) from the northeast,
toward the Equator, throughout the Antilles at the pres¬
ent time. These winds could provide some assistance
to bats moving southwards along the archipelago.

Increasingly sophisticated radars have detected
large birds flying within the eye of hurricanes (e.g.,

Hurricane Arthur in 2014, Hurricanes Hermine and
Mathew in 2016). The transport of birds by hurricanes
is not unusual (Tuck 1968; Dionne et al. 2008), but the
survival rate of birds lofted by different parts of a storm
is unknown. In terms of bats, Hurricane Ivan, which
passed over Grenada on 7 September 2004, presum¬
ably moved bats through the southern Lesser Antilles
(A. lituratus , Genoways et al. 2010) and the Cayman
Islands (A. jamaicensis, Fleming and Murray 2009).
Storms have also carried A. jamaicensis from St. John to
St. Croix (banded animal: Rafe Buolon, personal com¬
munication) and at least four species of bat ( Erophylla
sezekorni, Phyllonycteris poeyi, Artibeus jamaicensis,
and Phyllops falcatus ) from Cuba to Florida, with each
known from only one or two individuals and “have
only been found in the Florida Keys and south Miami”
(Florida Bat Conservancy 2017), but there is no evi¬
dence to suggest that any populations were established.

Several taxa would seem more capable of de¬
terministic dispersal between Lesser Antillean islands
(Lawlor 1986; Lomolino 1986; Patterson and Atmar
1986). This ability is driven by at least two things—
sheer size and power of the larger bats, and wing shape.
For example, the long narrow wing shape in P. davyi, T.
brasiliensis , and M. molossus supports efficient long¬
distance flights (aspect ratios of 8.0-9.0) (Norberg and
Rayner 1987; Vaughan et al. 2004; Marinello and Ber¬
nard 2014). At the other end of the spectrum, the short
round wings ofV. stramineus, M. buriri, A. nichollsi, S.
angeli, S. paulsoni, and M. martiniquensis and nyctor
(aspect ratios of 5.3-5.9) impose substantial limits on
long distance movement, deterministic or otherwise.
However, despite their small size and apparent fragility,
Natalus, Micronycteris, and Myotis are found on several
islands in the archipelago, thus indicating that they
are more robust than they appear, or are disturbance
adapted, or at least disturbance tolerant (Pedersen et
al. 1996, 2010, 2013; Arendt et al. 1999; Hilton et al.
2003; Frank et al. 2017).

Human impact. —An increasing number of
studies are reporting new fossil records of bats and
other vertebrates, in each case attributing population
declines, extirpation, and extinction of Caribbean bats
to humans (Steadman et al. 1984b, 2015; Pregill et al.
1988; Bailon et al. 2015; Soto-Centeno and Steadman
2015; Boudadi-Maligne et al. 2016; Stoetzel et al.
2016; Valente et al. 2017), rather than to sea level and

Pedersen et al.—Bats of Saint Lucia

climate change during the Holocene (sensu Davalos
and Russell 2012).

Beginning approximately 6,000 years ago, there
were four waves of human colonization of the West
Indies (Lithic, Archaic, Ceramic, and European), the
first from Mesoamerica and the next two from South
America (Davis 2000; Fitzpatrick and Keegan 2007;
Fitzpatrick 2012,2015; Siegel et al. 2015) and the last
from Europe. These movements were more likely influ¬
enced by seafaring technology and ocean currents than
by geographic distance. Paradoxically, the southern
islands of the Eesser Antilles were colonized relatively
late (Cooke et al. 2017), with the islands of St. Eucia
and St. Vincent being among the last to be occupied
by humans—1,395 and 1,650 years ago, respectively
(Fitzpatrick et al. 2015).

During the Archaic Age, volcanic activity was
more frequent south of the Guadeloupe Passage than to
the north. Indeed, the Soufriere volcano on St. Vincent
buried several prehistoric sites under a deep blanket of
ash, around 295 AD (Bullen and Bullen 1972). Such
eruptions may have been a deterrent to prehistoric
settlement in the southern Lesser Antilles (Callaghan
2007, 2010; Fitzpatrick 2012).

Bats were a common decorative motif on ceramic
vessels during the period 1,500 to 500 years ago (Fitz¬
patrick 2015; Giovas 2017), but there is only limited
zooarchaeological evidence of bats in the western
Caribbean (Newsom and Wing 2004). There is no evi¬
dence of consumption of bats as a food item and their
presence in these archaeological sites is most likely
incidental (but see Olson and Nieves-Rivera 2010). If
humans impacted bat populations it would have been
primarily driven by their destruction of roosts and for¬
est ecosystems.

As humans moved throughout the island chain,
they had an adverse impact on both floral and faunal
biodiversity (Wilson 1989; Versteeg and Schinkel
1992; Grouard 2001; Giovas et al. 2012; Giovas and
Fitzpatrick 2014; Braje et al. 2017) via the clearing of
native forest for the cultivation of invasive crop plants
(Richardson et al. 2000). Habitat alteration and destruc¬
tion intensified again with the increasing mechaniza¬
tion of agriculture by European colonists, over the last

41

500 years (Kimber 1988; Stoetzel et al. 2016). Early
humans were also responsible for the culinary-driven
extirpation of native vertebrates and invertebrates, the
introduction of “semi-domesticated” mammals from
South America (Giovas et al. 2012; Cooke et al. 2017;
Welch and Leppanen 2017), and the transmission of
zoonoses and parasites (Braje et al. 2017) to the native
mammals. The scale of these activities undoubtedly
varied from island to island (Rick et al. 2013). For
example, Carria 50 u is unusual among the islands of the
Lesser Antilles for its combination and concentration
of introduced South American mammals. Multiple
mammal introductions to the island occurred between
1,250 to 550 years ago, including peccary, guinea pig,
armadillo, opossum, and agouti.

Archaic, pre-Columbian, and colonial popula¬
tions of humans used caves and natural cavities for
shelter, but it is difficult to imagine how such use could
affect the bat population on St. Lucia differently than
those on the adjacent islands. However, caves and rock
shelters on St. Lucia were used heavily on a regular
basis throughout the 1790’s during the Brigand rebel¬
lions (Harmsen et al. 2012) and many of these were
subsequently destroyed by the British (Devaux 1997).
It is unlikely that destruction of multiple roost sites on
St. Lucia would extirpate entire species of bat, because
many “cave-obligate species” will adopt alternate roost
types if caves are not available (Rodriguez-Duran 2010;
Soto-Centeno and Steadman 2015). However, the loss
of even a single roost can impact an island’s fauna
(Genoways et al. 2007b) and the five insectivorous bats
that are missing on St. Lucia are typically considered
to be cave dwellers.

After surviving climate change and rising sea
levels from 15,000 to 9,000 years ago, it is difficult to
understand how so many cave dwelling species (pri¬
marily mormoopids) in the northern half of the Lesser
Antilles were presumably extirpated by small bands
of archaic humans some 6,000 years later (Steadman
et al. 1984a, 1984b, 2015; Pregill et al. 1988, 1994;
Soto-Centeno and Steadman 2015; Stoetzel et al. 2016).
However, these extinctions may be exaggerated by sur¬
vey effort and bias—caves are commonly visited during
both archeological and paleontological work in the
Antilles and caves provide a microenvironment where
the chances of fossilization are very good (Velazco

42

Special Publications, Museum of Texas Tech University

and Patterson 2013). Notably, fossils of Ardops and
Lasiurus appear in fossil strata that are well correlated
with climatic shifts (Stoetzel et al. 2016), but this is not
because these species inhabit the caves, it is because
their carcasses were incidentally carried back to the
roosts by the actual denizens of the cave—American
kestrels (Lenoble et al. 2014b) and owls (Bailon et al.
2015; Gala and Lenoble 2015; Steadman et al. 2015;
Stoetzel et al. 2016; Pelletier at al. 2017; Soto-Centeno
et al. 2017). In fact, owls would seem to have done an
excellent job at documenting bat biodiversity (Soto-
Centeno et al. 2017).

Island elevation and species diversity. —The
number of species found on an island is correlated
with the diversity of habitats available, which could
be affected more by elevation than island size per se
(MacArthur and Wilson 1967; Daltry 2009; Steinbauer
et al. 2016). This is because elevation influences plant
communities and habitat diversity in the West Indies,
which should equate to a greater diversity of bats on the
taller islands. Evaluation of such relationships is best
conducted via simple species-elevation and species-
area regression analyses (Mathews et al. 2015). The
relative position of an island above or below the “curve”
is of great importance; that is, those islands that fall
above the curve exceed their species richness as pre¬
dicted by either island area or elevation. Conversely,
those islands that fall below either of these curves fall
short of their predicted species richness.

Ricklefs and Lovette (1999) developed a species-
elevation curve for the Lesser Antilles using 15 islands
for which they had reliable survey data for four fau¬
nal groups (birds, bats, butterflies, and reptiles and
amphibians). Our log-log species-elevation curve is
more complete and is based on 25 islands in Lesser
Antilles (Fig. 16a, Table 4). The majority of these
data stem from our work conducted since the mid-
1970s on the islands of Anguilla, Antigua, Barbados,
Barbuda, Dominica, Grenada, Guadeloupe, Montser¬
rat, Nevis, Saba, St. Bart’s, St. Eustatius, St. Kitts, St.
Lucia, St. Maarten/St. Martin, St. Vincent, and five of
the Grenadine islands. Our curve also includes three
recent island records: Chiroderma improvisum from St.
Kitts (Beck et al. 2016) and Nevis (Burton Lim in 2016
and Kevel Lindsay in 2017, personal communication),

and M. plethodon from St. Eustatius (Pedersen et al.
2018) (Table 2). We found a significant relationship
between island elevation and species diversity (Table
4), whereas this was not the case for bats in the study
done by Ricklefs and Lovette (1999).

Six of the Limestone Caribbees (Anguilla,
Antigua, Barbuda, Grande-Terre Guadeloupe, Marie
Galante, and St. Maarten/Martin) fall above the curve,
indicating that they are more diverse than predicted
by their elevation (Fig. 16a). This may be tied to the
abundant caves on these islands, which provide critical
refugia for bats during the breeding season and in times
of natural disaster. Three of the Limestone Caribbees
(St. Bart’s, La Desirade, and Barbados) and five of the
Grenadines fall below the curve, this being attributed to
their small sizes and arid habitats. Barbados falls below
the line, but this may be due to its recent geological age
of about 1 million years.

All 11 of the Volcanic Caribbees have elevations
greater than 600 m and each has at least six species
of bat. Eight of these islands, including St. Lucia, sit
above the line and have at least nine species of bat. St.
Vincent is not only located above the line but outside
of the 95% percentile, thus indicating that it is signifi¬
cantly species-rich in comparison to its two neighbors.
Predictably, these data reflect the positive relationships
found among tall islands, habitat diversity, and diverse
bat communities. It follows, that high-elevation, wet
forests may serve as critical ecological refugia during
times of climate change in the future (LaVal 2004;
Soto-Centeno et al. 2017) and/or these tall islands may
serve as a “source” that could maintain the species pools
in the region, pursuant to natural or human-mediated
disasters (Carstensen et al. 2012).

Four of the 25 islands in this study are very flat
and have elevations of less than 250 m—two of these
islands are located at the north end of the chain (An¬
guilla and Barbuda), Grande-Terre Guadeloupe lies
in the middle, and Mustique lies to the south in the
Grenadines. The first three of these have more species
than their respective elevations would suggest and are
obvious outliers in Figure 16a. This is most likely a
consequence of the availability of abundant cave roosts
located on these particular islands.

Log species . Log species

Pedersen et al.—Bats of Saint Lucia

43

a.

1.2

0.9

0.4

St Vincent Dominica
Grenada • • •» Basse Terre

1.5

2.0

Log elevation

2.5

3.0

3.5

1.2

1.1

1.0

0.9

0.8

0.7

0.6

0.5

0.4

• Canouan

2.3 2.4 2.5 2.6 2.7 2.8 2.9 3.0 3.1 3.2 3.3

Log elevation

Figure 16. a) Species-elevation curve for 25 islands in the Lesser Antilles. Log species = 0.168 +0.254 x Log elevation,
R 2 = 0.351. b) Species-elevation curve for a subsample of 21 islands in the Lesser Antilles with a maximum elevation
of 250+ m. Log species = -0.789 + 0.590 x Log elevation, R 2 = 0.788.

Table 4. Regression analyses regarding island elevation, island size, and species richness for bat populations in the Lesser Antilles. Significance indicated
as follows: *P < 0.05; ** P < 0.01; and *** P < 0.001.

Special Publications, Museum of Texas Tech University

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Pedersen et al.—Bats of Saint Lucia

45

To explore the affect that these flat islands may
have on our understanding of the system, we con¬
ducted a separate analysis of a reduced data set of the
21 islands that exceed 250 m in maximum elevation.
This grouping is not inconsequential—habitats above
250 m are cooler and wetter due primarily to island¬
generated weather. As such, orographic wet forests
are found in the interior or on the leeward side of these
taller islands, which in concert serve as a more ecologi¬
cally appropriate data set against which to evaluate the
presumed “depauperate” fauna of St. Lucia (Fig. 16b).
Predictably, the explanatory power of this second
species-elevation curve increased substantially from
an R-squared of 0.35 to 0.79 (Table 4). Although the
positions of Martinique, St. Lucia, and St. Vincent did
not change relative to each other, their locations shifted
relative to the steeper curve. St. Lucia and Martinique
dropped to just below the line and all three islands fall
within the 95% confidence limits. Four of the eleven
volcanic Caribbees sit above the line, whereas five
of the Limestone Caribbees and Carria?ou sit above
the line in Fig. 16b. Two additional species-elevation
curves were derived, one for the Volcanic Caribbees
and the other for the Limestone Caribbees + Grenadines
(Table 4), but both had poor statistical support relative
to those data depicted in Fig. 16b.

Four species of bat were rarely netted outside of
moist forests on St. Lucia: 89% of the Monophyllus
were netted in forest, between 200 and 300 m (and
presumably at higher elevations); 95% of the Sturnira
captured were netted in forest, above 200 m (mostly
at 200-300 m); 41 of the 42 Ardops captured were
netted in forests within a very narrow range of eleva¬
tions, 294 to 319 m; and 92% of the Pteronotus were
netted in forest, above 250 m. The small number of
Monophyllus and Sturnira that were netted outside the
forest and below 200 m on St. Lucia probably represent
facultative foraging trips, rather than a para-montane
distribution, that is, species that roost at one elevation
but habitually forage at another (sensu Koopman 1983).
Of these, M. plethodon , S. paulsoni, and A. nichollsi
are Lesser Antillean endemics.

Endemism and species richness increase with
elevation on islands (Steinbauer et al. 2016). For those
islands listed in Table 2, the percent of endemic spe¬
cies differs between the Limestone Caribbees and the

Volcanic Caribbees, effectively a dichotomy between
those islands with maximum elevations either below
or above 600 m (39.6% and 50.5%, respectively). This
equates to having two additional endemic species on tall
volcanic islands and these are most often single-island
records of insectivorous moist forest bats (P. fuscus , M.
buriri, E. fuscus [Dominica], E. guadeloupensis, and
M. martiniquensis) (Table 2). Three of these ( P. fuscus ,
M. buriri , and M. martiniquensis ) have not been found
on St. Lucia. On St. Vincent, M. buriri has been netted
only in a narrow band of higher elevations (242-640
m), which may partially explain the absence of this
unique bat on St. Lucia. None of the plant-visiting
bats that are “missing” on St. Lucia (A. lituratus and
G. longirostris ) are elevation-restricted and only A.
jamaicensis x schwartzi is a Lesser Antillean endemic.

Despite this impression of a depauperate fauna,
St. Lucia has the predicted number of species for its ele¬
vation and the relative number of insectivorous bats that
were netted was similar to that of the adjacent islands
of Martinique and St. Vincent (16%, 13-19%) (Table
3). Enigmatically, this net-presence is effectively half
of that noted on islands with more comparable eleva¬
tions to the north (40%, 23-63%; Antigua, Barbuda,
Montserrat, Nevis, Saba, St. Eustatius, St. Kitts, and St.
Martin), which like St. Lucia, do not have moist forest
insectivorous bats.

Island area and the last glacial maximum. —We
derived a species-area curve based on 25 islands in
the Lesser Antilles (Fig. 17, Table 4). The slope of
our curve (0.223) is similar to that of Ricklefs and
Lovette (Slope = 0.232, 14 islands; see discussion
above; Ricklefs and Lovette 1999) and that of Willig et
al. (slope = 0.262,23 islands; Willig et al. 2010). With
its dearth of insectivorous bats, St. Lucia sits below the
line and outside of the 95% confidence limit in Figure
17. Conversely, St. Vincent sits above the line and
outside of the 95% confidence limit indicating that it
is as species-rich as St. Lucia is species-poor, in regard
to both island area and island elevation. This pattern is
seen in the other species-area curves listed in Table 4.

Most of the Volcanic Caribbees exhibit conical
aprons that may extend as far outward as 3,000 to 4,000
m from the current shoreline at a fairly constant depth
of 40-60 m. During the last glacial maximum, these

46

Special Publications, Museum of Texas Tech University

.a>

I

1.2

1.1

1.0

0.9

0.8

0.7

0.6

0.5

0.4

0.5 1.0 1.5 2.0 2.5 3.0 3.5

Log area

Figure 17. Species-area curve for 25 islands in the Lesser Antilles. Log species = 0.398 + 0.223 x Log area, R 2 = 0.730.

64*0'0"W 62*0'0*W 60°Q’Q"W

Figure 18. Bathymetric map of the Lesser Antilles. Dark
grey shading represents potential extent of exposed land
during the Pleistocene at last glacial maximum (26,500
to 19,000 years before present; sea levels -130 m below
present).

aprons were exposed as sea levels were -130 to 120 m
lower than present day, thereby increasing the absolute
size of these islands, but not necessarily increasing the
amount of habitat diversity usable by bats (Fig. 18).
Regardless, the distance between St. Vincent and St.
Lucia, and between St. Lucia and Martinique, would
have changed very little due to abrupt geological fea¬
tures (deep water passages) to the north and south of St.
Lucia. Despite changes in island area during the late
Pleistocene, these relatively static inter-island distances
would have made movement of bats among these three
islands much as it is today.

Davalos and Russell (2012) developed a model
to test if changes in sea level during the last glacial
maximum (LGM) were responsible for extirpations and
extinctions of bats throughout the Antilles. Their model
showed that island area during the LGM was well cor¬
related with species richness in the Greater Antilles and
Bahamas. However, their model indicated that island
area did not correlate well with species richness in the
Lesser Antilles, during the LGM. This they attributed to
a poor fossil record in the Lesser Antilles. Recent fos¬
sil data from Marie Galante would have affected their
results, but these data were not available to them at the
time, i.e., Stoetzel et al. (2016) and Royer et al. (2017).
Nevertheless, their model inexplicably neglected the
survey data published between 2003 and 2012 (by the

Pedersen et al.—Bats of Saint Lucia

47

authors) from seven islands: Saba, St. Kitts, Nevis,
Montserrat, Martinique, Grenada, and Barbados. Yet,
Davalos and Russell (2012) included Tintamarre, a
100-hectare island northeast of St. Maarten/Martin,
which does not have any bats. Their depauperate
2012 data were therefore insufficient to support their
claims regarding island area and species richness in
the Lesser Antilles, in either the past or the present.
Below, we redress their model with a more complete
data set and with more attention paid to the geologi¬
cal differences between the Volcanic and Limestone
Caribbees (Table 2).

Island elevation , island area , and the presence
of caves. —We used a multiple regression analysis (R
Development Core Team 2008) to investigate which
factor—island elevation or island area—best predicts
bat species richness in the Lesser Antilles (Table 5).
In the greater sample of 25 islands, the combination of
island elevation and island area accounts for 82% of
the overall variance (i?-squared = 0.8168) and island
area accounts for -60% of that. In the subsample of
21 islands that are 250 meters in elevation or higher,
island elevation and island area account for 88% of
the overall variance (R-squared = 0.8803) and island
elevation accounts for the majority of that (-47%). This
increase in /^-squared and the apparently greater effect
of island elevation on species richness is an artifact of
the reduced sample of islands with elevations greater
than 250 m (Table 4). This latter result supported our
assumption, and those of others, that island elevation
is an effective proxy for habitat diversity, plant biodi¬
versity, and hence species richness in the bat fauna.

However, island area better explains species
richness than does habitat diversity (elevation) for the
greater sample of 25 islands (Table 2). Though ecologi¬
cally counterintuitive, this result is driven primarily by
three islands that have far more species than predicted
by their elevation: Anguilla, Barbuda, and Grande-Terre
(Guadeloupe) (Fig. 16a). Despite their relative dearth
of habitat, the abundant caves on these islands have
made them ecological sinks (Pulliam 1988; Carstensen
et al. 2012) that tend to “collect” species. This result
not only underlines the importance of cave conserva¬
tion on islands (Genoways et al. 2007b), but also infers
that simple regression models of biodiversity that do
not consider the presence of caves may be illusory.

Perhaps, the apparently lower number of caves on the
Volcanic Caribbees may be a reason for the lower than
anticipated numbers of bats on these islands, of which
St. Lucia is an obvious example.

Implications of the Artibeus hybrid swarm. —The
identification of naturally occurring hybridization
events is incredibly important from the perspective of
evolutionary biology. This is because hybrid zones
provide a unique window into the evolutionary tempo
of the formation of genetic isolating mechanisms and
the speciation process. Therefore, robust evidence
of chiropteran hybridization is critical to the under¬
standing of bat evolution and speciation. Although
bats are one of the most speciose clades of mammals,
documented cases of naturally occurring hybridiza¬
tion events are rare and only a handful of putative bat
hybrid zones have been identified to date. This pattern
is likely a consequence of poor taxon sampling and
the limited deployment of genomic datasets that have
the resolving power to elucidate ongoing or historical
hybridization events.

Arguably one of the most well-defined bat hy¬
brid zones is the Artibeus hybrid zone in the southern
Lesser Antilles. This is because the data supporting
hybridization among species of Caribbean Artibeus
spans decades of research and includes a number of in¬
dependent datasets (e.g., nuclear AFLPs, mitochondrial
DNAgenotyping and sequencing, and morphometries)
that collectively provide strong support for ongoing
hybridization (see Artibeus jamaicensis x schwartzi
species account above; Jones and Phillips 1976; Pumo
et al. 1988; Phillips et al. 1989; P. Larsen et al. 2010).
When examining the collective scope of these available
datasets, alongside subfossil records from the Greater
Antilles, genetic data from both Central and South
American Artibeus populations, and an evolutionary
timescale of diversification events within Artibeus (see
P. Larsen et al. 2007,2010,2013), several critically im¬
portant patterns emerge with respect to the origin of the
Artibeus hybrid swarm that centers on the islands of St.
Lucia and St. Vincent in the southern Lesser Antilles.
It is important to note that these patterns are consistent
with recent hypotheses regarding rapid hybrid specia¬
tion on insular systems and they are intimately tied
to and likely facilitated by aspects of classical island
biogeography (P. Larsen et al. 2010; Lamichhaney

48

Special Publications, Museum of Texas Tech University

Table 5. Multiple regression analyses regarding species elevation and species area curves for bat populations

the Lesser Antilles. Significance

indicated

as follows: * P < 0.05;

** P < 0.01; and ***

P< 0.001.

All 25 islands in the study

Multiple regression

Estimate

Std error

t ratio

Intercept

0.099

0.105

0.95

Log Elevation

0.136

0.042

3.23**

Log Area

0.191

0.256

7 48 ***

Multiple R-square = 0.813

ANOVA

DF

Sum of sauares

Mean square

F ratio

Model

2

0.674

0.337

49.06***

Error

22

0.151

0.007

Total

24

0.825

Effect tests

Sum of sauares

F ratio

Log Elevation

1

0.071

10.435**

Log Area

1

0.384

55.907***

Islands with elevations above 250 meters (n

Multiple regression

= 21)

Estimate

Std error

t ratio

Intercept

-0.440

0.178

-2.49*

Log Elevation

0.385

0.077

4 9g***

Log Area

0.113

0.030

3 73**

Multiple R-square = 0.878

ANOVA

DF

Sum of sauares

Mean sauare

F ratio

Model

2

0.599

0.299

66.18***

Error

18

0.081

0.004

Total

20

0.681

Effect tests

Sum of sauares

F ratio

Log Elevation

1

0.112

24.769***

Log Area

1

0.062

13.892**

et al. 2018). These patterns include: 1) primary and
secondary contact among evolutionary young conge¬
ners (including non-sister lineages) across an insular
system; 2 ) primary or secondary contact occurring
on small and ecologically monotypic islands; and 3)
geographic position of a genetically and morphologi¬
cally distinct phenotype on islands that are at the very
center of an active hybrid zone. Each of these patterns
are associated with the Artibeus hybrid zone in the
southern Lesser Antilles, and they collectively provide
the foundation for the hypothesis of a hybrid origin of
A. schwartzi (P. Larsen et al. 2010). Moreover, they
provide a unique window into the evolution of genetic

isolating mechanisms within stenodermatine bats, the
most recently evolved and most speciose clade of the
Phyllostomidae. This is because hybridization among
Artibeus jamaicensis, A. planirostris, and A. schwartzi
on islands in the southern Lesser Antilles indicates
that ~4 million years of evolution was an insufficient
amount of time to evolve complete genetic isolating
mechanisms (occurring in the absence of allopatric
reinforcement; see P. Larsen et al. 2013).

The significance of the geographic location of A.
schwartzi being at the center of an insular hybrid zone
cannot be understated. This is because the distinct

Pedersen et al.—Bats of Saint Lucia

49

phenotype is consistent with the hypothesis that hybrid
speciation is facilitated by the disruption of parental
gene flow due to classical island biogeography, e.g.,
fluctuating island size and colonization success be¬
ing tied to fluctuating climate and ecology (P. Larsen
et al. 2010). In light of this observation, as well as
the remarkably similar hypothesis of hybrid origins
of Galapagos finches (Lamichhaney et al. 2018), we
recommend additional studies aimed at identifying
hybrid zones associated with insular systems. Targeting
these hybrid zones using advanced genomic technolo¬
gies will likely identify additional instances of hybrid
speciation and will provide new, dynamic perspectives
on biological evolution.

The depauperate bat fauna on St. Lucia remains
an enigma .—The bat populations in the Lesser Antilles
are shaped by asynchronous variation in speciation,
colonization, and extinction rates among taxa. These
are affected by more than just island complexify and
isolation alone. As we have noted elsewhere, the adap¬
tion of the bats themselves to the new island conditions
can shape these numbers (Kwiecinski et al. 2018). In
turn, biodiversity data sit precariously atop differential
survey bias, idiosyncrasies or a lack of a fossil record,
the asynchronous shifting of the ITCZ, the stochastic
effects of major storms and shifting of the trade winds,
the influence of humans during the last 2,000 years, and
certainly the looming effects of climate change in the
next 200 years (Gannon and Willig 2010; Pedersen et
al. 2010; Rodriguez-Duran 2010; Willig et al. 2010;

Conenna et al. 2017). As such, biodiversity estimates
and conservation guidelines can only be approxima¬
tions at best and almost certainly underestimate the
true faunal diversity of any of the Lesser Antillean
islands. There remains a need to collect and interpret
data on natural dispersal so that movements between
the mainland and islands and among oceanic islands
themselves become understood and that the natural
barriers to dispersal are better defined.

Despite this daunting collection of unknowns,
the enigmatic bat fauna of St. Lucia begs further study
and analysis. Are the species discussed above actually
“missing” from the chiropteran fauna of St. Lucia? This
could change with the next additional field expedition
to the island (sensu Lindsay et al. 2010; Beck et al.
2016). In the future, acoustic surveys should be utilized
to help focus mist netting efforts. Such efforts must
also include searches for caves and other natural roosts.
Therein, efforts to locate owl roosts and owl pellets
could provide evidence of species of bat that evade mist
nets and/or cavernicolous species that are roosting in
undisclosed caves or seeking shelter in non-cave roosts.
Finally, because island-dwelling bats face increasing
threats to their environments by humans (Jones et al.
2003; Conenna et al. 2017), we advocate for future
research efforts to be directed towards understanding
the natural history of the least-known island endemic
species system-wide and to apply what funding there
is to conservation efforts.

Acknowledgements

We thank Alwin Dornelly (Head of Research,
Department of Forestry) for his tremendous efforts
in all phases of our survey work on St. Lucia. We
thank Michael Anthony (Head of Wildlife), Michael
Bobb (Senior Forestry Officer), and Alwin Dornelly
for arranging the MOU that supported our survey ef¬
forts and for Michael Andrew (Chief of Forestry) for
providing the Export Permit. We appreciate the help
of the Department of Forestry with communications
and guidance to potential netting sites. In particular,
we thank the Department of Forestry for arranging for
their Officers and others to meet us at several localities:
Tim Baptiste at Marquis Estate; Alwin Dornelly and
Matt Morton, Woodland Estate; Lester Jean-Baptiste,

Edmond Forest Reserve; Stephen Lesmond, Quilesse
Forest Reserve Trail; Adam Michelle, Forestiere Nature
Trail; and the Soufriere Marine Management Associa¬
tion. Robert J. Devaux OBE kindly provided his expert
knowledge of the island’s geography, history, and the
locations of several caves that we surveyed for bats.
Our work on St. Lucia was also made possible by the
cooperation and good humor extended to us by several
landowners who gave us access to their properties and
by Corporal Elias Auguste of the Micoud Police.

We thank our colleagues for sharing their un¬
published survey data with us: Rafe Buolon, Francis
Catzeflis, Burton Lim, and Kevel Lindsay.

50

Special Publications, Museum of Texas Tech University

We appreciate the cooperation of the following
curators and collection managers for allowing us access
to study specimens in their care: Nancy B. Simmons,
American Museum of Natural History (AMNH);
Richard W. Thorington, Jr., and Linda K. Gordon,
National Museum of Natural History (NMNH); Robert
M. Timm, University of Kansas (KU); Robert J. Baker
and Heath Gamer, Museum of Texas Tech University
(TTU); Patricia W. Freeman and Thomas E. Labedz,
University of Nebraska State Museum (UNSM). We

also appreciate the statistical assistance provided by
Jennifer Krauel (University of Tennessee, Knoxville).

Angie Fox, Technical Artist, University of Ne¬
braska State Museum, prepared the distribution maps.
Finally, we want to acknowledge the field assistance
of our colleagues: Brandon Bales, Matt Clarke, Jeff
Corneil, Jennifer Krauel, Matt Morton and Rachael
Pedly (Durrell Wildlife), and Mike Roedel.

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Pedersen et al.—Bats of Saint Lucia

59

Addresses of authors:

Scott C. Pedersen

Department of Biology and Microbiology
South Dakota State University
Brookings , SD 57007
scottpedersen@sdstate. edu

Gary G. Kwiecinski

Department of Biology
University of Scranton
204 Monroe Avenue
Scranton , PA 18510
gary. kwiecinski@scranton. edu

Hugh H. Genoways

University of Nebraska State Museum
W436 Nebraska Hall
Lincoln , NE 68588
hgenowaysl@unl. edu

Roxanne J. Larsen

Department of Veterinary and Biomedical Sciences

College of Veterinary Medicine

University of Minnesota

Saint Paul, MN 55108

rlarsen@umn. edu

Peter A. Larsen

Department of Veterinary and Biomedical Sciences

College of Veterinary Medicine

University of Minnesota

Saint Paul, MN 55108

plarsen@umn. edu

Carleton J. Phillips

Department of Biological Sciences and Museum
Texas Tech University
Lubbock,, TX 79409
carl.phillips@ttu. edu

Robert J. Baker [Deceased]

Department of Biological Sciences and Museum
Texas Tech University
Lubbock ,, TX 79409

60

Special Publications, Museum of Texas Tech University

Appendix

St. Lucia Gazetteer .—The coordinates for collecting sites that we visited during our survey were determined by
using a Garmin eTrex handheld GPS system. Coordinates for sites where other collectors conducted the work
were taken from the specimens, published records, or other reference material, including online St. Lucia gazet¬
teers and maps.

Locality

Quarter

Fatitude

Fongitude

Elevation (m)

Anse Chastanet

Soufriere

13°52'00.9"N

61°04T0.3"W

—

Anse La Raye

Anse Fa Raye

13 o 56'30.3"N

61°02'28.2"W

1

“Anse La Raye” = Venus Estate

Anse Fa Raye

13°55T4.7"N

61°01T2.1"W

—

Au Leon Peak

Dennery

13°57T4.4"N

60°54'07.1 M W

319

Barre de l’lsle Ridge

Castries

13 0 55'35.3 M N

60°57'32.0"W

294

Black Bay

Vieux Fort

13°44'36.0"N

60 o 58'55.5"W

100

Boguis

Dauphin

14°00'41.7"N

60°55'08.6"W

35

Canelles River

Micoud

13°46'59.6"N

60°54'53.1"W

10

Castries

Castries

14°00 , 36.7"N

60°59T5.0"W

10

Cul de Sac River (near Deglos)

Castries

13°58'29.rN

60°58'36.0"W

34

Dennery River

Dennery

13°54'34.6"N

60°54T6.2"W

11

Des Cartier Rainforest Trail

Micoud

13°50'24.2"N

60°58'45.9 M W

—

Diamond Botanical Garden

Soufriere

13°51'08.7"N

61°02'57.5"W

47

“Durocher” = Morne Durocher

Praslin

13°52'34.4"N

60°56T2.5"W

—

Edmund Forest Reserve

Soufriere

13 o 50'31.8"N

61°00T6.0"W

550

Forestiere Trail Head

Castries

13°58T1.2"N

60°57'08.8"W

300

Fox Grove Inn

Praslin

13°51'47.0"N

60°54'22.8"W

52

Grace Cave

Vieux Fort

13 o 47'57.0"N

60°58'43.6"W

165

Mamiku River

Praslin

13°52'02.8"N

60°54'05.0"W

3

Marigot Bay

Castries

13 o 57'50.0"N

61°01'34.0"W

5

Marquis Estate

Dauphin

14°01'35.2"N

60°54'40.6"W

25

Millet Forest (= Millet Bird Sanctuary)

Anse Fa Raye

13°53'44.7"N

60°59'50.2"W

—

Monchy

Dauphin

14°03T0.7"N

60°56'03.2"W

25

near Piaye

Faborie

i3°46'05.i"N

61°01'54.6"W

—

Piton Flore

Castries

13°57'51.6"N

60°56'24.0"W

300

Quilesse

Micoud

13°50'23.1"N

60°58'25.8"W

283

Raillon Negres

Praslin

13°52'25.3"N

60°56'09.6"W

255

River Doree

Choiseul

13°46'05.1"N

61°01'54.6 M W

—

Saltibus

Faborie

13°48'59.8"N

60°00'21.9"W

398

Sorciere River*

Dauphin

14°0r26.0"N

60°54'33.2"W

—

Soufriere Cave

Soufriere

13°51'29.1"N

61°03'52.2"W

0

Pedersen et al.—Bats of Saint Lucia

61

Locality

Quarter

Latitude

Longitude

Elevation (m)

Troumassee River

Micoud

13°49T3.9"N

60°54'53.7"W

40

Union Nature Trail

Castries

14°01T4.2"N

60°57'41.8"W

18

Union Agricultural and Research Station

Gros Islet

14°02'00.0"N

60°58'00.0"W

30.5

Woodlands Estate

Vieux Fort

13°47'54.7"N

60°58'50.7"W

226

*We did not plot the Sorciere River site on the map (Fig. 12) for the Artibeus jamaicensis x schwartzi hybrid
because we are uncertain of its exact location. It is entered above exactly as reported by Clarke (2009), albeit
converted from his UTM designation [13°59'06.7"N, 60°53'21.4"W], This location is near our site in the
Marquis Estate, Dauphin Quarter.